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Preparation of 2-fluoromalonic esters and related compounds from hexafluoropropene
Journal of Fluorine Chemisfry, 25 (1984) Received:
June 27, 1983; accepted:
September
PREPARATION OF P-FLUOROMALONIC -FLUOROPROPENE
Nobuo
ISHIKAWA*,
Department
of Chemical
Tokyo 152 (Japan)
12
203
25, 1983
ESTERS AND RELATED
Akio TAKAOKA
Meguro-ku,
203-2
COMPOUNDS
FROM HEXA-
and M. Kamal IBRAHIM+
Technology,
Tokyo
Institute
of Technology,
Ookayama,
SUMMARY
Dimethyl propene
and diethyl
by its exhaustive
fluoromalonates alcoholysis
alcoholysis.
Fluoromalonates
were condensed
with o-phenylenediamine
were prepared
or alternatively
thus obtained
from hexafluoroits ammonolysis
or their alkylated
or its substituted
and
derivatives
derivatives
to
give a number of lH-3-fluoro-1,5-dibenzodiazepin-Z,4(3H,5~)-diones.
INTRODUCTION
Fluoromalonic heterocycles
esters
which
point of view [l]. malonic
esters
condensation conditions derived exchange
have appeared
from ethyl fluoroacetate
however,
are tedious
[7].
0022-l
and diethyl
chloromalonate
giving only poor yields.
139/84/$3.00
which
Department,
of diethyl oxalate
of monofluoro-
include
1) the
under basic
fluoroxalacetate
[2], 3) the halogen-
with KF or KHF2 at a high
of diethyl malonate addition
The starting
are either expensive
+ On leave from Chemistry
for the preparation
decomposition
(C103F) [6], and 5) the Michael esters
for monofluoro from the physiological
and ethyl chloroformate
[3-51, 4) the fluorination
trifluoroacrylic methods,
of diethyl
attention
in the literature,
of ethyl fluoroacetate
reaction
intermediates
receiving
A number of methods
[2], 2) the thermal
temperature fluoride
are versatile
are recently
with perchloryl
of a methoxide
materials
or reagents
ion to for these
and/or toxic, and the procedures Among them, perchloryl
Cairo University,
fluoride
is
Cairo, Egypt.
0 Elsevier Sequoia/Printed
in The Netherlands
204 known as a unique
fluorinating
it always gives a mixture which
are difficult
reagent
of mono- and di-fluorinated
to a hydroxide
acid by the exhaustive available
groups, but
methylene
compounds
to separate.
The fact that a fluorine isoelectronic
for active methylene
atom in an organic molecule group suggested
hydrolysis
perfluoroalkene
is a substituent
us to prepare a fluoromalonic
of hexafluoropropene,
a commercially
with low toxicity.
2H20 >
CF3CF=CF2
CF3CHFiOH
-2HF
A
0
(
HO;-CHF-;OH
0
Actually an alcohol conducted afforded
this process
esters
5H)-diones
-2HF
by using an alkoxide
Alternatively
we prepared
ester
organic
molecules,
ion in
the first step was Either method
in a good yield without
and their alkylated
for monofluorinated
For example,
I
to give tetrafluoropropionitrile.
the monofluoromalonic
Fluoromalonic blocks
has been performed
b
2H20
0
to give the malonic esters. by ammonolysis
CF2=CF-!OH -HF
compounds
any danger.
are useful building
especially
fluoroheterocycles.
a number of lH-3-fluoro-1,5-benzodiazepin_2,4(3H,
by condensation
with
c-phenylenediamines.
RESULTS AND DISCUSSION
Exhaustive
alkoxylation
of hexafluoropropene
in an alcohol.
into a solution
of a sodium methoxide
hexafluoropropyl methyl
methyl
ether
alkoxylated
by Knunyants
of (2a) followed
group giving the ortho-ester
methoxide
in methanol dimethyl
again.
acid
This partially The dehydro-
of the terminal
(3a) was carried
gave
difluoro-
out using a sodium
The ortho ester was treated with acid and
fluoromalonate
based on hexafluoropropene.
[8].
which
with sulfuric
to the second alcoholysis.
by the methanolysis
methylene
the resultant
at low temperature,
(2a) on treatment
and his co-workers
product was subjected
fluorination
in methanol
using a
gas was introduced
(la) was formed quantitatively,
2,3,3,3-tetrafluoropropionate
as was reported
was conducted
When hexafluoropropene
sodium alkoxide
(4a) was obtained
in 50 - 55% yield
20 RO-/ROH CF3CF=CF2
H30+
A
CF3CHFCF20R
>
CF3CHF;OR
(-2HF)
0
(la) R = Me
(2a) R
(lb) R = Et
(2b) R = Et
= Me
[CF2CFiORl-_
[+
H30+ (R0)3C-CHFCOR
)
RO,j-CHF-$OR
bl
0
(3)
(4)
(3a) R = Me
(4a) R = Me
(3b) R = Et
(4b) R = Et
Diethyl ethoxide
fluoromalonate
in ethanol
An alternative
(4b) was also obtained
in a similar manner route to dialkyl
tetrafluoropropionitrile
(5).
by Knunyants'
solvent.
We improved
to a dialkyl
of hexafluoropropene
ammonia
considerably
in dioxane
giving
fluoromalonate
as a
by using
or tetrahydrofuran,
The nitrile was isolated
(90 - 95%) by dehydrofluorination
hydrolysis
is the way through
group [9], who used dioxane
the yield of the nitrile
in the latter.
was converted
(Table 1).
Ammonolysis
a large excess of cont. aqueous especially
by using a sodium
fluoromalonates
the nitrile was reported
yield
b
in
-80%
yield,
and
in one pot and in excellent with an alkoxide,
followed
by
with acid.
NH3
CF3CF=CF2
>
CF3CHFC~
RO
[CF~;CFCN]
1
(5) RO$-CHF-;OR 0 (4); (4a) R=Me,
0 (4b) R=Et
(
RO-/ROH 1) RO[Rob-CHFCN] 2) H30+
0
('c/mmHg)
R
ME
Et
Me
Et
No.
(2a)
(Zb)
(4a)
(4b)
63
71
1
6 ppm
(J Hz)
,-F _F 11.3; JCF3_H 6.0;
H-F 47.4)
o Lit: [lo].
(J H-F 46.2)
117.5, d (CHF)
I (J
JH_F 39.5)
JH_F 44.7)
(cF~); 1Z7.5, dq (CHF)
JcF _H 5.6;
117.;, d (CHF)
I (J
0.5,3dd
(J cF _F 9.4;
Appm
alcoholysis
of
5.33, d (CHF)
1.33, t (CH3); 4.37, q (CH2)
i 5.23, d (CHF)
3.90, s (CH3)
[ 5.10, dq (CHF)
1.33, t (CH3); 4.34, q (CH2)
5.5, dq (CHF)
3.85, s (CH3)
1 H
(4) by exhaustive
0, dd (CF3); 129.0, dq (CHF)
19Fa
NMR (CDCl3)
(2) and 2-fluoromalonates
b Lit: [8].
1770
1765
1775
1780
74
82
(cm
-1
IR [CO,R]
0)
a Upfield from ext. CF3C02H.
[82-83/l]'
llO-111/22
i [SO-83/13]'
loo-102/22
[[108-109]b
108-109
I-[951b
'95-96
B.p. [Lit]
Compd.
Yield
of 2,3,3,3-tetrafluoropropionates
hexafluoropropene
Preparation
TABLE 1
207 Comparing
the latter process
to the former,
the nitrile
(5) required
step giving
(4) gave a better yield
but the second
than the second alcoholysis
Thus the former process was suitable
former.
the first step giving
a longer time and larger apparatus,
in the
for a large scale reaction
though the total yield was lower. The hydrogen
atom of the fluoromethylene
was removed by an alkoxide treating with alkyl halides
the instability
malonic
of the carbanion
and the fluorine
CHF(CO2R)2
+
CF(C02R)2
due to the I,
(6) (6a) R = Me
= n-BuBr
(6b) R = Et
between
i.e., B-diketones,
gives 1,5_benzodiazepine
o-phenylenediamines
B-dialdehydes,
compounds
ester could be used as a B-dicarbonyl
[ll].
component
1&3-fluoro-l,5-benzodiazepin-2,4(3H,5N)-diones yields
between
R'-CF(C02R)2
= EtBr
It is well known that the reaction fi-dicarbonyl compounds,
repulsion
to
atom.
R'X = Me1
(4)
Pdiesters,
This must be attributed
ester.
RO-/ROH __L___,
R'X
esters
by an alkyl group by
The reaction was more sluggish
(Table 2).
than that of a non-substituted
the carbanion
group in fluoromalonic
ion and was replaced
and
B-ketoesters
or
Z-Fluoromalonic
in the above reaction (7) were obtained
and
in good
(Table 3) 0 NH2
X
t
NH2
EtOC' 'CCR EtOC' F \\ 0
R F
+ X
(7) Not only 2-fluoromalonic used as the component, 5H)-diones.
derivatives. underway.
reactions
derivatives
were also
were carried out by refluxing
in a sodium ethoxide-ethanol
The nitrogen thus obtained
esters but its 2-alkyl
giving lN-3-fluoro-3-alkyl-1,5-benzodiazepin_2,4(3H,
These condensation
both components
: (7a)-(79)
mixture
for several
atoms of the lH-3-fluoro-1,5-benzodiazepine
could be methylated The biological
with methyl
activity
iodide giving
hours.
derivatives 1,5-dimethyl
tests for these compounds
are now
208
aSee
(nc)
(79)
[ (nc)
(7f)
[ (nc)
(7e)
[ (nc)
(7d)
I(nc)
((7~)
[ (nc)
(7b)
[(nc)
H
H
H
NO2
Cl
Me
Table 1,
Bu
Et
Me
H
H
H
a.
204
283
245
262
)300
)300
>300
H
(7a)
H
(OC)
R
No.
X
M.p.
Compd.
50
60
60
50
40
70
60
(%)
Yield
1690
1660
1680
1690
1690
1670
1680
t-co1
3200
3350
3340
3260
3200
(7)
[(:";;.;)
(
(J 39.5)
119.5 d
[(:3,",;'
[,:I,",;"
((;3;,;,;'
ppm (J Hz)
lgFa
NMR
[NH1 6
IR (cm-')
lH-3-Fluoro-1,5-dibenzodiazepin-2,4(3H,5H)-diones
TABLE 3
: I?;;;5;::5: s (Ar-H);
[;'~~,",(~~!$;)7~'"
Zg2)
s (Ar-K);
s (Ar-!!);
m (Ar-tj);
L 10.45 s (Ntjx2)
7.40-8.10
5.70 d (CHj);
j:,f;,d,(W'I;,'.l~
[::Z
[:,;;,d,(W!!F;)7.16
6 ppm
lH
r,::::;i,
[(;;:;;)
I(45.19)
44.54
[(;'4:;;)
i(:::::,
[(:;:;:,
11.13 (11.19)
6.06
(K:)
(;;:;;)
(17.56)
17.29
(;;:;;)
(Z)
(;;:;:)
N (X)
(6.04)
(::G)
(;:;;)
(2.52)
2.53
(;:Z';)
(Z)
(::;;)
H (X)
(Calcd)
c (%)
Anal
210
EXPERIMENTAL
Route via tetrafluoropropionate Hexafluoropropene of sodium methoxide ice-bath.
water,
gas (255 g, 1.70 mol) was introduced
(94 g. 1.74 mol) in methanol
The gas was completely
1 h of stirring
and the resulting
added dropwise,
resulting
ether
the temperature
After
h.
into
The oil was
sulfuric
acid (400 ml) was
The mixture
into ice water,
was
the the
After being washed with aq. NaHC03 Distillation
it was dried over MgS04.
2,3,3,3-tetrafluoropropionate
~3
was poured
to give a crude product of
below 30 'C.
thrown
oily layer was separated.
mixture
(la) (400 ml).
vessel and concentrated
then with water,
(500 ml), cooled in an
the reaction
for 1 h at room temperature,
solution methyl
keeping
methyl
into a solution
in a course of
oily layer separated
in a polyethylene
stirred
absorbed
at room temperature,
1,1,2,3,3,3-hexafluoropropyl placed
(2a)
gave
(2a) (203 g, 74%), bp 94 - 96 'C
(Lit [8]: bp 95 'C). To a solution
of sodium methoxide
(800 ml) the methyl below 30 'C.
After
ester
(205 g, 3.8 mol) in methanol
(2a) was added dropwise
30 min of stirring
poured
for
1 h at room temperature,
into ice water.
the ethereal saturated reduced
extract
112 'C/45 mmHg
filtered,
The oily material
was extracted
fluoromalonate
the mixture
suspension
was
and the filtrate was
and dried over MgS04.
gave dimethyl
with ether and then with
Distillation
under
(4a) (137 g, 71%), bp 111 -
(Lit [lo]: bp 80 - 83 'C/13 mmHg).
In a similar manner tetrafluoropropionate obtained
The resulting
was washed with aq. NaHC03 solution,
NaCl solution,
pressure
the temperature
at room temperature,
was made acidic with cont. HCl (250 ml). stirred
keeping
using sodium ethoxide
in ethanol,
ethyl 2,3,3,3-
(2b), bp 108 - 109 'C (Lit [8]: 108 - 109 'C) was
in 82% yield.
Diethyl
fluoromalonate
(4b), bp 110 - 111 'C/20 mmHg (Lit [lo]: bp
97 - 97.5 'C/l2 mmHg) was then obtained
Route via tetrafluoropropionitrile
Aqueous
ammonia
in 63% yield.
(5)
(25%, 500 g, 7.35 mol) and 1,4-dioxane
(200 ml) were
put into a 1 2 three necked flask fitted with a dry ice-acetone a thermometer
and an inlet gas filter.
Hexafluoropropene
condenser,
(291 g,
1.94
211 mol) was introduced temperature
into the solution
at -5 - 0 OC.
the oil which had separated water,
was extracted
washed with
gave 2,3,3,3-tetrafluoropropio-
(5) (187 g. 76%), bp 40 'C (Lit [9]: bp 40 - 41 'C).
To a solution the nitrile
and stirred
of sodium methoxide
(190 g, 3.5 mol) in methanol
(5) (127 g, 1.0 mol) was added dropwise
below 10 'C.
The reaction
mixture
was allowed
for 30 min, and was then acidified
min of stirring water.
the
at this temperature,
with toluene,
Distillation
and dried over MgS04.
nitrile
in a course of 5 h, keeping
After 3 h of stirring
at room temperature,
aq. NaHC03 solution,
over MgS04, distillation
to warm to room temperature
under reduced
was poured
with diethyl
then with saturated
(800 ml)
the temperature
with cont. HCl.
the mixture
The oily product was extracted
keeping
into ice
ether, washed with
NaCl solution.
pressure
After 30
After drying
gave dimethyl
fluoromalonate
(4a) (138 g, 92%), bp 90 - 91 'C/15 mmHg.
Dimethyl
n-butylfluoromalonate
Into a solution fluoromalonate stirred
of sodium
(2.3 g, 0.1 mol) in ethanol
at room temperature
for 30 min and n-butyl
was added dropwise
and the whole was refluxed
mixture
was worked
up as usual and distillation
diethyl
n-butylfluoromalonate
'C/25 mmHg
(6b, R' = n-Bu)
(100 ml), diethyl
The mixture
(17.8 g, 0.1 mol) was added dropwise.
bromide
was
(14 g, 0.1 mol)
The reaction
for 1 h.
under reduced
pressure
gave
(17.9 g, 84%), bp 133 - 135
(Lit [lo]: 54 - 55 'C/O.07 mmHg).
In a similar manner,
diethyl methylfluoromalonate
104 - 105 'C/23 mmHg, was obtained
To a solution
of a sodium ethoxide
were added o-phenylenediamine (1.8 g, 10 mmol). to stand overnight
(6b, R' = Me), bp
in 74% yield.
(0.68 g, 10 mmol)
in ethanol
(1.1 g, 10 mmol) and diethyl
The resulting
suspension
at room temperature.
with aq. HCl and the precipitate
was refluxed
P-ethyl- or 2-butyl-Z-fluoromalonate
and diethyl
were condensed
was acidified
and recrystallized
(1.2 g, 60%), mp >300
In a similar manner, o-phenylenediamine fluoro-1,5-benzodiazepin-2,4(3H,5H)-diones.
fluoromalonate for 5 h and allowed
The reaction mixture
formed was collected
from acetic acid, giving the pure product
(10 ml)
'C.
2-methyl-,
to give l&3-alkyl-3-
212
To a mixture
of lH-3-fluoro-1,5-benzodiazepin-2,4(3H,5H)-dione
and sodium ethoxide was added dropwise reaction
(20 mmol)
in ethanol
mixture was acidified,
Recrystallization in 55% yield,
(20 ml), methyl
over 30 min, and refluxed
mp
gave colorless
(20 mmol)
On cooling,
for 3 h.
and resultant
from methanol
iodide
(10 mmol)
precipitate needles
the
was collected.
of the pure product
300 Oc.
REFERENCES 1 Reviews:
a) R. Filler,
and Their
Industrial
b) W. G. M. Jones,
in R. E. Banks
Applications,
ibid., p.154;
Filler and Y. Kobayashi Chemistry,
Kodansha,
2 E. D. Bergmann,
Organofluorine London,
Biomedicinal
1982, p.1;
S. Cohen and I. Shakak,
Aspects
in R.
of Fluorine
d) A. J. Elliot, J. Chem. SOC.,
Chemicals
1979, P.123;
c) R. Filler and S. M. Naovi,
(Editors),
Tokyo,
(Editor),
Ellis Horwood,
ibid., -___
p.55.
(1959) 3278,
3286. 3 E. Gryszkievicz-Trochmovski,
A. Sporzynski
and Wnuk, Rec. trav. chim.,
-66 (1947) 413. 4 A. Y. Yakubovich 5 Y. I. Bogodist
and I. N. Belyaeva,
and L. D. Protsenko,
Zhur. Obshch. Russ.P.1185,
Khim., -31 (1961) 2119.
878 (1966); Chem.
Abstr., -67 (1966) 2777r. 6 H. Gershan, -81
J. A. A. Renwick,
W. K. Kynn and R. E'Ascali,
3. Org. Chem.,
(1966) 916.
7 0. Paleta and J. Konarck, 8 M. D. Bargamova,
Collect.
Y. A. Cheburkov,
Czech. Chem. Commun., -38 (1973) 66. B. L. Dyatkin,
P. V. Petrovskii
and
I. L. Knunyants,
Izv. Akad Nauk SSSR, Ser Khim.,
(1967) 611.
9 I. L. Knunyants,
L. S. German and B. L. Dyatkin,
Izv. Akad Nauk SSSR Otdel
Khim. Nauk,
(1956) 1353.
10 F. L. M. Pattison,
R. L. Buchanan
and F. H. Dean, Can. J. Chem., -43
(1965) 1700. 11 See, for example
J. A. Barltrop,
C. G. Richards,
(in part) G. Ryback, J. Chem. Sot., and D. R. Marshall, Lett.,
ibid.,
D. M. Russell
(1959) 1132; D. Lloyd, R. H. McDougall
(1965) 3785; R. Barchet
(1964) 2239; R. E. Pastor,
C. A. Giovannoni
Europ. J. Med. Chem., 2 (1974) 175.
and
and K. W. Merz, Tetra and A. R. Cambon,
June 27, 1983; accepted:
September
PREPARATION OF P-FLUOROMALONIC -FLUOROPROPENE
Nobuo
ISHIKAWA*,
Department
of Chemical
Tokyo 152 (Japan)
12
203
25, 1983
ESTERS AND RELATED
Akio TAKAOKA
Meguro-ku,
203-2
COMPOUNDS
FROM HEXA-
and M. Kamal IBRAHIM+
Technology,
Tokyo
Institute
of Technology,
Ookayama,
SUMMARY
Dimethyl propene
and diethyl
by its exhaustive
fluoromalonates alcoholysis
alcoholysis.
Fluoromalonates
were condensed
with o-phenylenediamine
were prepared
or alternatively
thus obtained
from hexafluoroits ammonolysis
or their alkylated
or its substituted
and
derivatives
derivatives
to
give a number of lH-3-fluoro-1,5-dibenzodiazepin-Z,4(3H,5~)-diones.
INTRODUCTION
Fluoromalonic heterocycles
esters
which
point of view [l]. malonic
esters
condensation conditions derived exchange
have appeared
from ethyl fluoroacetate
however,
are tedious
[7].
0022-l
and diethyl
chloromalonate
giving only poor yields.
139/84/$3.00
which
Department,
of diethyl oxalate
of monofluoro-
include
1) the
under basic
fluoroxalacetate
[2], 3) the halogen-
with KF or KHF2 at a high
of diethyl malonate addition
The starting
are either expensive
+ On leave from Chemistry
for the preparation
decomposition
(C103F) [6], and 5) the Michael esters
for monofluoro from the physiological
and ethyl chloroformate
[3-51, 4) the fluorination
trifluoroacrylic methods,
of diethyl
attention
in the literature,
of ethyl fluoroacetate
reaction
intermediates
receiving
A number of methods
[2], 2) the thermal
temperature fluoride
are versatile
are recently
with perchloryl
of a methoxide
materials
or reagents
ion to for these
and/or toxic, and the procedures Among them, perchloryl
Cairo University,
fluoride
is
Cairo, Egypt.
0 Elsevier Sequoia/Printed
in The Netherlands
204 known as a unique
fluorinating
it always gives a mixture which
are difficult
reagent
of mono- and di-fluorinated
to a hydroxide
acid by the exhaustive available
groups, but
methylene
compounds
to separate.
The fact that a fluorine isoelectronic
for active methylene
atom in an organic molecule group suggested
hydrolysis
perfluoroalkene
is a substituent
us to prepare a fluoromalonic
of hexafluoropropene,
a commercially
with low toxicity.
2H20 >
CF3CF=CF2
CF3CHFiOH
-2HF
A
0
(
HO;-CHF-;OH
0
Actually an alcohol conducted afforded
this process
esters
5H)-diones
-2HF
by using an alkoxide
Alternatively
we prepared
ester
organic
molecules,
ion in
the first step was Either method
in a good yield without
and their alkylated
for monofluorinated
For example,
I
to give tetrafluoropropionitrile.
the monofluoromalonic
Fluoromalonic blocks
has been performed
b
2H20
0
to give the malonic esters. by ammonolysis
CF2=CF-!OH -HF
compounds
any danger.
are useful building
especially
fluoroheterocycles.
a number of lH-3-fluoro-1,5-benzodiazepin_2,4(3H,
by condensation
with
c-phenylenediamines.
RESULTS AND DISCUSSION
Exhaustive
alkoxylation
of hexafluoropropene
in an alcohol.
into a solution
of a sodium methoxide
hexafluoropropyl methyl
methyl
ether
alkoxylated
by Knunyants
of (2a) followed
group giving the ortho-ester
methoxide
in methanol dimethyl
again.
acid
This partially The dehydro-
of the terminal
(3a) was carried
gave
difluoro-
out using a sodium
The ortho ester was treated with acid and
fluoromalonate
based on hexafluoropropene.
[8].
which
with sulfuric
to the second alcoholysis.
by the methanolysis
methylene
the resultant
at low temperature,
(2a) on treatment
and his co-workers
product was subjected
fluorination
in methanol
using a
gas was introduced
(la) was formed quantitatively,
2,3,3,3-tetrafluoropropionate
as was reported
was conducted
When hexafluoropropene
sodium alkoxide
(4a) was obtained
in 50 - 55% yield
20 RO-/ROH CF3CF=CF2
H30+
A
CF3CHFCF20R
>
CF3CHF;OR
(-2HF)
0
(la) R = Me
(2a) R
(lb) R = Et
(2b) R = Et
= Me
[CF2CFiORl-_
[+
H30+ (R0)3C-CHFCOR
)
RO,j-CHF-$OR
bl
0
(3)
(4)
(3a) R = Me
(4a) R = Me
(3b) R = Et
(4b) R = Et
Diethyl ethoxide
fluoromalonate
in ethanol
An alternative
(4b) was also obtained
in a similar manner route to dialkyl
tetrafluoropropionitrile
(5).
by Knunyants'
solvent.
We improved
to a dialkyl
of hexafluoropropene
ammonia
considerably
in dioxane
giving
fluoromalonate
as a
by using
or tetrahydrofuran,
The nitrile was isolated
(90 - 95%) by dehydrofluorination
hydrolysis
is the way through
group [9], who used dioxane
the yield of the nitrile
in the latter.
was converted
(Table 1).
Ammonolysis
a large excess of cont. aqueous especially
by using a sodium
fluoromalonates
the nitrile was reported
yield
b
in
-80%
yield,
and
in one pot and in excellent with an alkoxide,
followed
by
with acid.
NH3
CF3CF=CF2
>
CF3CHFC~
RO
[CF~;CFCN]
1
(5) RO$-CHF-;OR 0 (4); (4a) R=Me,
0 (4b) R=Et
(
RO-/ROH 1) RO[Rob-CHFCN] 2) H30+
0
('c/mmHg)
R
ME
Et
Me
Et
No.
(2a)
(Zb)
(4a)
(4b)
63
71
1
6 ppm
(J Hz)
,-F _F 11.3; JCF3_H 6.0;
H-F 47.4)
o Lit: [lo].
(J H-F 46.2)
117.5, d (CHF)
I (J
JH_F 39.5)
JH_F 44.7)
(cF~); 1Z7.5, dq (CHF)
JcF _H 5.6;
117.;, d (CHF)
I (J
0.5,3dd
(J cF _F 9.4;
Appm
alcoholysis
of
5.33, d (CHF)
1.33, t (CH3); 4.37, q (CH2)
i 5.23, d (CHF)
3.90, s (CH3)
[ 5.10, dq (CHF)
1.33, t (CH3); 4.34, q (CH2)
5.5, dq (CHF)
3.85, s (CH3)
1 H
(4) by exhaustive
0, dd (CF3); 129.0, dq (CHF)
19Fa
NMR (CDCl3)
(2) and 2-fluoromalonates
b Lit: [8].
1770
1765
1775
1780
74
82
(cm
-1
IR [CO,R]
0)
a Upfield from ext. CF3C02H.
[82-83/l]'
llO-111/22
i [SO-83/13]'
loo-102/22
[[108-109]b
108-109
I-[951b
'95-96
B.p. [Lit]
Compd.
Yield
of 2,3,3,3-tetrafluoropropionates
hexafluoropropene
Preparation
TABLE 1
207 Comparing
the latter process
to the former,
the nitrile
(5) required
step giving
(4) gave a better yield
but the second
than the second alcoholysis
Thus the former process was suitable
former.
the first step giving
a longer time and larger apparatus,
in the
for a large scale reaction
though the total yield was lower. The hydrogen
atom of the fluoromethylene
was removed by an alkoxide treating with alkyl halides
the instability
malonic
of the carbanion
and the fluorine
CHF(CO2R)2
+
CF(C02R)2
due to the I,
(6) (6a) R = Me
= n-BuBr
(6b) R = Et
between
i.e., B-diketones,
gives 1,5_benzodiazepine
o-phenylenediamines
B-dialdehydes,
compounds
ester could be used as a B-dicarbonyl
[ll].
component
1&3-fluoro-l,5-benzodiazepin-2,4(3H,5N)-diones yields
between
R'-CF(C02R)2
= EtBr
It is well known that the reaction fi-dicarbonyl compounds,
repulsion
to
atom.
R'X = Me1
(4)
Pdiesters,
This must be attributed
ester.
RO-/ROH __L___,
R'X
esters
by an alkyl group by
The reaction was more sluggish
(Table 2).
than that of a non-substituted
the carbanion
group in fluoromalonic
ion and was replaced
and
B-ketoesters
or
Z-Fluoromalonic
in the above reaction (7) were obtained
and
in good
(Table 3) 0 NH2
X
t
NH2
EtOC' 'CCR EtOC' F \\ 0
R F
+ X
(7) Not only 2-fluoromalonic used as the component, 5H)-diones.
derivatives. underway.
reactions
derivatives
were also
were carried out by refluxing
in a sodium ethoxide-ethanol
The nitrogen thus obtained
esters but its 2-alkyl
giving lN-3-fluoro-3-alkyl-1,5-benzodiazepin_2,4(3H,
These condensation
both components
: (7a)-(79)
mixture
for several
atoms of the lH-3-fluoro-1,5-benzodiazepine
could be methylated The biological
with methyl
activity
iodide giving
hours.
derivatives 1,5-dimethyl
tests for these compounds
are now
208
aSee
(nc)
(79)
[ (nc)
(7f)
[ (nc)
(7e)
[ (nc)
(7d)
I(nc)
((7~)
[ (nc)
(7b)
[(nc)
H
H
H
NO2
Cl
Me
Table 1,
Bu
Et
Me
H
H
H
a.
204
283
245
262
)300
)300
>300
H
(7a)
H
(OC)
R
No.
X
M.p.
Compd.
50
60
60
50
40
70
60
(%)
Yield
1690
1660
1680
1690
1690
1670
1680
t-co1
3200
3350
3340
3260
3200
(7)
[(:";;.;)
(
(J 39.5)
119.5 d
[(:3,",;'
[,:I,",;"
((;3;,;,;'
ppm (J Hz)
lgFa
NMR
[NH1 6
IR (cm-')
lH-3-Fluoro-1,5-dibenzodiazepin-2,4(3H,5H)-diones
TABLE 3
: I?;;;5;::5: s (Ar-H);
[;'~~,",(~~!$;)7~'"
Zg2)
s (Ar-K);
s (Ar-!!);
m (Ar-tj);
L 10.45 s (Ntjx2)
7.40-8.10
5.70 d (CHj);
j:,f;,d,(W'I;,'.l~
[::Z
[:,;;,d,(W!!F;)7.16
6 ppm
lH
r,::::;i,
[(;;:;;)
I(45.19)
44.54
[(;'4:;;)
i(:::::,
[(:;:;:,
11.13 (11.19)
6.06
(K:)
(;;:;;)
(17.56)
17.29
(;;:;;)
(Z)
(;;:;:)
N (X)
(6.04)
(::G)
(;:;;)
(2.52)
2.53
(;:Z';)
(Z)
(::;;)
H (X)
(Calcd)
c (%)
Anal
210
EXPERIMENTAL
Route via tetrafluoropropionate Hexafluoropropene of sodium methoxide ice-bath.
water,
gas (255 g, 1.70 mol) was introduced
(94 g. 1.74 mol) in methanol
The gas was completely
1 h of stirring
and the resulting
added dropwise,
resulting
ether
the temperature
After
h.
into
The oil was
sulfuric
acid (400 ml) was
The mixture
into ice water,
was
the the
After being washed with aq. NaHC03 Distillation
it was dried over MgS04.
2,3,3,3-tetrafluoropropionate
~3
was poured
to give a crude product of
below 30 'C.
thrown
oily layer was separated.
mixture
(la) (400 ml).
vessel and concentrated
then with water,
(500 ml), cooled in an
the reaction
for 1 h at room temperature,
solution methyl
keeping
methyl
into a solution
in a course of
oily layer separated
in a polyethylene
stirred
absorbed
at room temperature,
1,1,2,3,3,3-hexafluoropropyl placed
(2a)
gave
(2a) (203 g, 74%), bp 94 - 96 'C
(Lit [8]: bp 95 'C). To a solution
of sodium methoxide
(800 ml) the methyl below 30 'C.
After
ester
(205 g, 3.8 mol) in methanol
(2a) was added dropwise
30 min of stirring
poured
for
1 h at room temperature,
into ice water.
the ethereal saturated reduced
extract
112 'C/45 mmHg
filtered,
The oily material
was extracted
fluoromalonate
the mixture
suspension
was
and the filtrate was
and dried over MgS04.
gave dimethyl
with ether and then with
Distillation
under
(4a) (137 g, 71%), bp 111 -
(Lit [lo]: bp 80 - 83 'C/13 mmHg).
In a similar manner tetrafluoropropionate obtained
The resulting
was washed with aq. NaHC03 solution,
NaCl solution,
pressure
the temperature
at room temperature,
was made acidic with cont. HCl (250 ml). stirred
keeping
using sodium ethoxide
in ethanol,
ethyl 2,3,3,3-
(2b), bp 108 - 109 'C (Lit [8]: 108 - 109 'C) was
in 82% yield.
Diethyl
fluoromalonate
(4b), bp 110 - 111 'C/20 mmHg (Lit [lo]: bp
97 - 97.5 'C/l2 mmHg) was then obtained
Route via tetrafluoropropionitrile
Aqueous
ammonia
in 63% yield.
(5)
(25%, 500 g, 7.35 mol) and 1,4-dioxane
(200 ml) were
put into a 1 2 three necked flask fitted with a dry ice-acetone a thermometer
and an inlet gas filter.
Hexafluoropropene
condenser,
(291 g,
1.94
211 mol) was introduced temperature
into the solution
at -5 - 0 OC.
the oil which had separated water,
was extracted
washed with
gave 2,3,3,3-tetrafluoropropio-
(5) (187 g. 76%), bp 40 'C (Lit [9]: bp 40 - 41 'C).
To a solution the nitrile
and stirred
of sodium methoxide
(190 g, 3.5 mol) in methanol
(5) (127 g, 1.0 mol) was added dropwise
below 10 'C.
The reaction
mixture
was allowed
for 30 min, and was then acidified
min of stirring water.
the
at this temperature,
with toluene,
Distillation
and dried over MgS04.
nitrile
in a course of 5 h, keeping
After 3 h of stirring
at room temperature,
aq. NaHC03 solution,
over MgS04, distillation
to warm to room temperature
under reduced
was poured
with diethyl
then with saturated
(800 ml)
the temperature
with cont. HCl.
the mixture
The oily product was extracted
keeping
into ice
ether, washed with
NaCl solution.
pressure
After 30
After drying
gave dimethyl
fluoromalonate
(4a) (138 g, 92%), bp 90 - 91 'C/15 mmHg.
Dimethyl
n-butylfluoromalonate
Into a solution fluoromalonate stirred
of sodium
(2.3 g, 0.1 mol) in ethanol
at room temperature
for 30 min and n-butyl
was added dropwise
and the whole was refluxed
mixture
was worked
up as usual and distillation
diethyl
n-butylfluoromalonate
'C/25 mmHg
(6b, R' = n-Bu)
(100 ml), diethyl
The mixture
(17.8 g, 0.1 mol) was added dropwise.
bromide
was
(14 g, 0.1 mol)
The reaction
for 1 h.
under reduced
pressure
gave
(17.9 g, 84%), bp 133 - 135
(Lit [lo]: 54 - 55 'C/O.07 mmHg).
In a similar manner,
diethyl methylfluoromalonate
104 - 105 'C/23 mmHg, was obtained
To a solution
of a sodium ethoxide
were added o-phenylenediamine (1.8 g, 10 mmol). to stand overnight
(6b, R' = Me), bp
in 74% yield.
(0.68 g, 10 mmol)
in ethanol
(1.1 g, 10 mmol) and diethyl
The resulting
suspension
at room temperature.
with aq. HCl and the precipitate
was refluxed
P-ethyl- or 2-butyl-Z-fluoromalonate
and diethyl
were condensed
was acidified
and recrystallized
(1.2 g, 60%), mp >300
In a similar manner, o-phenylenediamine fluoro-1,5-benzodiazepin-2,4(3H,5H)-diones.
fluoromalonate for 5 h and allowed
The reaction mixture
formed was collected
from acetic acid, giving the pure product
(10 ml)
'C.
2-methyl-,
to give l&3-alkyl-3-
212
To a mixture
of lH-3-fluoro-1,5-benzodiazepin-2,4(3H,5H)-dione
and sodium ethoxide was added dropwise reaction
(20 mmol)
in ethanol
mixture was acidified,
Recrystallization in 55% yield,
(20 ml), methyl
over 30 min, and refluxed
mp
gave colorless
(20 mmol)
On cooling,
for 3 h.
and resultant
from methanol
iodide
(10 mmol)
precipitate needles
the
was collected.
of the pure product
300 Oc.
REFERENCES 1 Reviews:
a) R. Filler,
and Their
Industrial
b) W. G. M. Jones,
in R. E. Banks
Applications,
ibid., p.154;
Filler and Y. Kobayashi Chemistry,
Kodansha,
2 E. D. Bergmann,
Organofluorine London,
Biomedicinal
1982, p.1;
S. Cohen and I. Shakak,
Aspects
in R.
of Fluorine
d) A. J. Elliot, J. Chem. SOC.,
Chemicals
1979, P.123;
c) R. Filler and S. M. Naovi,
(Editors),
Tokyo,
(Editor),
Ellis Horwood,
ibid., -___
p.55.
(1959) 3278,
3286. 3 E. Gryszkievicz-Trochmovski,
A. Sporzynski
and Wnuk, Rec. trav. chim.,
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and I. N. Belyaeva,
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Zhur. Obshch. Russ.P.1185,
Khim., -31 (1961) 2119.
878 (1966); Chem.
Abstr., -67 (1966) 2777r. 6 H. Gershan, -81
J. A. A. Renwick,
W. K. Kynn and R. E'Ascali,
3. Org. Chem.,
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7 0. Paleta and J. Konarck, 8 M. D. Bargamova,
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Y. A. Cheburkov,
Czech. Chem. Commun., -38 (1973) 66. B. L. Dyatkin,
P. V. Petrovskii
and
I. L. Knunyants,
Izv. Akad Nauk SSSR, Ser Khim.,
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L. S. German and B. L. Dyatkin,
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Khim. Nauk,
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10 F. L. M. Pattison,
R. L. Buchanan
and F. H. Dean, Can. J. Chem., -43
(1965) 1700. 11 See, for example
J. A. Barltrop,
C. G. Richards,
(in part) G. Ryback, J. Chem. Sot., and D. R. Marshall, Lett.,
ibid.,
D. M. Russell
(1959) 1132; D. Lloyd, R. H. McDougall
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(1964) 2239; R. E. Pastor,
C. A. Giovannoni
Europ. J. Med. Chem., 2 (1974) 175.
and
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