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Selective fluorination of substituted methanols with methanesulfonyl fluoride and cesium fluoride as modified with crown ethers
Journal of Fluorine Chemistry, 35 (1987)
677-683
677
Received: December 5, 1986; accepted: January 30, 1987
PRELIMINARY NCYTE
*ielective Fluoride
Fluorinatio d
H&hgnesulfonvl
.
and Cesium Fluor ide as Modified
with Crown Ethers
K. MAKINO** and I-I. YOSHIOKA*
The Institute
of Physical
Wake, Saitama 351-01
and Chemical Research
(RIKEN)
(Japan)
SUMMARY
A new combination as modified selective
with
18-crown_(j
fluorination
substitution.
of methanesulfonyl
was demonstrated
of various
benzyl
As extended applications
I-fluoromethylpyrazole-4-carboxylate phthalimide
u2>
corresponding
Although
there
monofluoromethyl light
owing to synthetic
Ltd.,
Address;
Tsuboi-cho,
0022-l 139/87/$3.50
dravbacks
Central Funabashi,
via
nucleophilic
procedure,
ethyl
from the
respectively.
synthons
containing
to be of particular
Research Cbiba
with low selectivity
Institute,
a
interest
they have seldom materialized associated
for
and N-fluoromethyl-
u1>
are many potential
group appearing
alcohols
in high yields
(4> and chloride
of never drug designs,
*qermanent
@)
and cesium fluoride
to be the best
of this
have been synthesized
alcohol
fluoride
Nissan
in the
to date or
Chemical
Ind.,
274 (Japan) 0 Elsevier Sequoia/Printedin The Netherlands
678
the unsatisfactory primary
nature
alcohols,
substrates.
of existing
chlorides
For example,
or bromides
fluorinations
even with the ones specifically require media,
‘forcing that
quarternary
fluoride
containing
by the strong
substitution, described when it
(CsF) but it
above. is
also
demands the sort
with crown ethers,
briefly
of forcing
aromatics
with a crown ether,
on heterocyclic
rings.
4-methoxybenzyl
alcohol
in THF under reflux crown ether 12-crown-4
for
(Table
< dibenzo-2Q-crown-8
ether,
demonstrated
of benzyl
to N-C&OH and
in combination
increased
with CsF and MsF
the promoting
in the following
< 15-crown-5
The effect
in Run 3. where the yield
was maximized in sharp contrast
effect
of
order:
< dicyclohexyl-18-crown-8
of the fluorination
of crown ethers.
but the etherification
so
(J.) was chosen as a substrate
We found that
The selectivity
dependent on the species
selectivity
1).
the fluorination
< TDA-1 < 18-crown-g.
was best
were screened
improved
following
N-CI&Cl
crown ethers
as
in acetonitrile
fluorination
extended application
and various
conditions
has been limited
by MsF, and its
Firstly,
respect.
with CsF is
esterification groups
destroyed
nucleophilic
though this
a new facile
with CsF as coupled
In this
for
in conversion
example of polychlorinated
We now report
alcohols
known to be useful
in most
to certain
which were easily
is
A
with
option
to be inapplicable
polar
substrates.
modification
can be a superior
group,
generally
in a strongly
of the ammoniumfluoride.
The efficiency
coupled
to a single
[Z].
the N-mOH
basicity
cesium fluoride
far
[l]
activation,
of unstable
or our recent
(MsF)
metal fluorides,
heating
in decomposition
but we have now found this
substrates
for
of
the most accessible
with alkali
prepared
ammoniumfluoride,
methanesulfonyl cases,
results
fluorinations
for
as usually
under severe
conditions*
often
reagents
was quite
of crown ether
as well
as the
to the Run 9 without
of 1 became dominant in the latter
crown case.
679
TABLE
1
Fluorination
of 4-Methoxybenzyl
Alcohol with Cesium Fluoride -
Methanesulfonyl
Fluoride(MsF)
- Crown Ether(CE)
Me0
CSF/MSF/CE M
Me0
1
MsF (eq)
2 3 4 5 6
4 4 4 4 2.2 4
2 2 2 2 1.2 2
7
4
2
8 9
4 4
2 2
1
+
MeD~CH2OCH2~DMe
_z
CsF (eq)
Run
CH2F
1
Yield(%) 3 7 12-CE-4(l) 15-CE-5(l) 18-CE-6(l) 18-CE-6cO.l) 18-CE-6C0.3) Dicyc.hexyl18-CE-6(0.1) Dibenzo24-CE-8(0.1) TDA-l(O.1)
16 47 80 66 75 28
32 22 Trace 7 7 26
9
32
38 0
23 40
rO?wJe
TD.4-l
A variety of benzyl fluorides could be prepared by the current procedure in good or moderate yields (Table Z), among which the fluorides with an electron-donatinggroup on the p-position or the E-position were found to be rather unstable, undergoing an auto-decompositionon standing.
TABLE
2
Fluorination
of Substituted
Benzyl Alcohols
CsF/MsF/lB-CE-6
X
CH20H
CH2F THF
Run
X
1
4-OMe
2 3 4 5 6 7 8
3-OMe
2-OMe 4-OCH2$ 2,5-diOMe 4-Me 4-Cl I-CF3
React. time(h) 5 5 5 5 5 15 15 5
Yield ($1 80 40 23 74 35 55 72 70
Chemical shifttppm) 5.26 5.34 5.44 5.29 5.41 5.32 5.31 5.44
Coupling const (Hz) 48.6 47.7 47.9 48.6 41.1 48.1 47.7 41.0
680
Next,
we found that
heterocycles
bearing
this
method could
a N-C&OH group.
I-hydroxymethylpyrazole-4-carboxylate into
ethyl
vith
CsF (4 eq)
(Table (6)
as coupled
The formation
as a result
negligible,
(4)
as indicated
in place
with MsF (2 eq)
could
be readily
3. Potassium
with the former and the application
a total
decomposition
of the substrate
3
Fluorination
in 76% yield
fluoride
was found that
proceed
TABLE
[A]
and l&crown-6
were respectively
of CsF, and it
pyrazole-4-carboxylate
(6)
converted
(1 eq)
of the C-N bond was virtually
in Table
fluoride
ethyl
ethyl
of bis(4-ethoxycarbonylpyrazol-l-yl)methane
of cleavage
tetra-n-butylammonium procedure
For example,
I-fluoromethylpyrazole-4-carboxylate
3).
[B]
be extended to certain
(g)
and
applied
in this
the reaction
of the latter affording
did not
resulted
a mixture
of
cz> and 6.
of Ethyl l-Hydroxymethylpyrazole-4-carboxylate
CsF/18-CE-b/MsF > THF
Run 1 2 3 4
CsF
MsF
(es)
(eq)
4 4 4 2.2
2 2 2 1.2
18-CE-6 (eq) 1 1 0.3 0.3
React. temp. r.t. rfl. rfl. rfl.
React. time(h) 20 : 4
Yield(%) -5 23 0 188
e 60 zz 61
s 0 2-3 3-4 3-4
in
681
The current procedure was similarly applied to a fluorination of N-hydroxymethylphthalimide(9). but we found that bis(N-phthalimidyl)methane 0)
[C] was a major product though accompanied by a trace of
N-fluoromethylphthalimideuz). Hence, we turned to the fluorination of N-chloromethylphthalimide(II). The reaction proceeded smoothly vith CsF (1.2 eq) as modified with 18-crown-6 (0.3 eq) at room temperature and afforded I2 [D] in 76% yield (Table 4).
l_o
TABLE
4
Fluorination
of N-Chloromethylphthalimide
0 CsF/l8-CE-6 THF
r .t . 2Oh L2
RUII 1 2 3 4
CSF (eq) 4 142 1:2
18-CE-6 (eq) 1 0.3 0.3
Yield(%) L?
1:
37 64 76 21
22 5 4 0
30-35%
682
Since properties that
little
has been published
of the N-CH2F group on N-heterocycles,
the fluorine
active
to date about characteristic it
is noteworthy
atom in li: was shown to be nucleophilically
as the chlorine
atom in 11, while
enough to remain intact
I
on every
as
the one in 6 was stable
treatment
as applied
to 12.
OH/NaH , &NC"20a THF
In conclusion, fluorination
r.t.
this
of various
0
method would be of wide applicability primary
alcohols
or its
transient
to the
groups
on
N-heterocycles.
A
A typical
reaction
To a suspension (1.5
g)
procedure
for
the synthesis
of CsF (712 mg, 4.69 mmol) and molecular
in 5 ml of dry THF, was added l&crown-6
nunol) at room temperature stirring
is described
for
under stirring
of 6:
sieves
4A
(310 rug, 1.17
in nitrogen.
After
1 h. MsF (230 mg, 2.35 mmol) and 4 (200 mg, 1.18 mmol)
vas added at room temperature celite-filtration
and refluxed
of the mixture
solvent
was evaporated
acetate
solution
and ethyl
was washed vith
for
using ‘a small acetate
4 h. After amount of THF, the
was added.
water and dried
The ethyl
on anhydrous
683
sodium sulfate.
After
removal of the solvent,
chromatographed on silica obtain
the residue
gel with chloroform
was
as an eluent
154 mg (76%) of 6. mp 44-45 “C. ir(KBr):
3415,
to
1698, 1560,
1449, 1410, 1250, 1224, 1189, 1136, 1028, 992, 962, and 770 cm-l. 6 1.36(3H,
pmr(CDC13)
t,
d, J=52.1 Hz), 8.02(1H, 60.61(t),
83.18(t),
162.31 (s).
J=7.1 Hz), 4.32(2H, s),
and 8.14(1H,
92.30(t),
s).
117.80(s),
q. 3~7.1 Hz), 6.29(2I-l,
mp 239-240 “C. ir(KBr):
s),
3425,
6 1.33(6H.
7.94(2H,
peak),
1212. 951, 730, and 768 cm-l. 7.60-8.00(8H,
and
3400, 1723, 1705, 1555, 1382, 1290,
ms m/z 292(M+), 264, 247(base C m;
143.05(d),
and 127.
1248, 1231, 1029, and 764 cm-*. pmr(CX13) 4.28(4H,
cmr(CEC13) 6 14.33(q),
134.42(d),
ms III/Z 172(M+>, 144(base peak),
B 8; mp 145-146 “C. ir(KBr):
q, J=7.1 Hz), 6.02(2H,
s),
t,
J=7.1 Hz),
and 8.16(W,
s).
236, 153, and 168.
1769, 1719, 1432, 1390, 1311,
pmr(CDC13) 6 5.64(2H,
m). ms m/z 306(M+, base peak),
s),
250, 222,
and 160, 132,
and 104. D E;
mp 83-84 “C. ir(KBr):
3480,
1290, 972, 722, and 708 cm-l. and 7.6@8,10(4H, 131.69(s), peak),
1
1780, 1722, 1468, 1418, 1364, 1328,
pmr(CDC13) 6 5.77(2R,
m) . cmr(CDC13) 6 70.55(t),
134.91 (d) , 166.36(s),
d, J=52.1 Hz),
79.33(t),
and 166.46(s).
124.14(d).
ms m/z 179(W,
160, 151, 135. 132, 123, and 104.
M. Shimizu, Y. Rakahara, and H. Yoshioka,
Tetrahedron L&t..
(1985) 4207. 2
base
V. V. Aksenov. V. M. Vlasov, V. P, Fadeeva, V. S. Chertok, Chem., 24 (1985) 73.
I. Il. Moryakina, P. P. Rodionov, and G. C. Yakobson, J. Fluorine
a
677-683
677
Received: December 5, 1986; accepted: January 30, 1987
PRELIMINARY NCYTE
*ielective Fluoride
Fluorinatio d
H&hgnesulfonvl
.
and Cesium Fluor ide as Modified
with Crown Ethers
K. MAKINO** and I-I. YOSHIOKA*
The Institute
of Physical
Wake, Saitama 351-01
and Chemical Research
(RIKEN)
(Japan)
SUMMARY
A new combination as modified selective
with
18-crown_(j
fluorination
substitution.
of methanesulfonyl
was demonstrated
of various
benzyl
As extended applications
I-fluoromethylpyrazole-4-carboxylate phthalimide
u2>
corresponding
Although
there
monofluoromethyl light
owing to synthetic
Ltd.,
Address;
Tsuboi-cho,
0022-l 139/87/$3.50
dravbacks
Central Funabashi,
via
nucleophilic
procedure,
ethyl
from the
respectively.
synthons
containing
to be of particular
Research Cbiba
with low selectivity
Institute,
a
interest
they have seldom materialized associated
for
and N-fluoromethyl-
u1>
are many potential
group appearing
alcohols
in high yields
(4> and chloride
of never drug designs,
*qermanent
@)
and cesium fluoride
to be the best
of this
have been synthesized
alcohol
fluoride
Nissan
in the
to date or
Chemical
Ind.,
274 (Japan) 0 Elsevier Sequoia/Printedin The Netherlands
678
the unsatisfactory primary
nature
alcohols,
substrates.
of existing
chlorides
For example,
or bromides
fluorinations
even with the ones specifically require media,
‘forcing that
quarternary
fluoride
containing
by the strong
substitution, described when it
(CsF) but it
above. is
also
demands the sort
with crown ethers,
briefly
of forcing
aromatics
with a crown ether,
on heterocyclic
rings.
4-methoxybenzyl
alcohol
in THF under reflux crown ether 12-crown-4
for
(Table
< dibenzo-2Q-crown-8
ether,
demonstrated
of benzyl
to N-C&OH and
in combination
increased
with CsF and MsF
the promoting
in the following
< 15-crown-5
The effect
in Run 3. where the yield
was maximized in sharp contrast
effect
of
order:
< dicyclohexyl-18-crown-8
of the fluorination
of crown ethers.
but the etherification
so
(J.) was chosen as a substrate
We found that
The selectivity
dependent on the species
selectivity
1).
the fluorination
< TDA-1 < 18-crown-g.
was best
were screened
improved
following
N-CI&Cl
crown ethers
as
in acetonitrile
fluorination
extended application
and various
conditions
has been limited
by MsF, and its
Firstly,
respect.
with CsF is
esterification groups
destroyed
nucleophilic
though this
a new facile
with CsF as coupled
In this
for
in conversion
example of polychlorinated
We now report
alcohols
known to be useful
in most
to certain
which were easily
is
A
with
option
to be inapplicable
polar
substrates.
modification
can be a superior
group,
generally
in a strongly
of the ammoniumfluoride.
The efficiency
coupled
to a single
[Z].
the N-mOH
basicity
cesium fluoride
far
[l]
activation,
of unstable
or our recent
(MsF)
metal fluorides,
heating
in decomposition
but we have now found this
substrates
for
of
the most accessible
with alkali
prepared
ammoniumfluoride,
methanesulfonyl cases,
results
fluorinations
for
as usually
under severe
conditions*
often
reagents
was quite
of crown ether
as well
as the
to the Run 9 without
of 1 became dominant in the latter
crown case.
679
TABLE
1
Fluorination
of 4-Methoxybenzyl
Alcohol with Cesium Fluoride -
Methanesulfonyl
Fluoride(MsF)
- Crown Ether(CE)
Me0
CSF/MSF/CE M
Me0
1
MsF (eq)
2 3 4 5 6
4 4 4 4 2.2 4
2 2 2 2 1.2 2
7
4
2
8 9
4 4
2 2
1
+
MeD~CH2OCH2~DMe
_z
CsF (eq)
Run
CH2F
1
Yield(%) 3 7 12-CE-4(l) 15-CE-5(l) 18-CE-6(l) 18-CE-6cO.l) 18-CE-6C0.3) Dicyc.hexyl18-CE-6(0.1) Dibenzo24-CE-8(0.1) TDA-l(O.1)
16 47 80 66 75 28
32 22 Trace 7 7 26
9
32
38 0
23 40
rO?wJe
TD.4-l
A variety of benzyl fluorides could be prepared by the current procedure in good or moderate yields (Table Z), among which the fluorides with an electron-donatinggroup on the p-position or the E-position were found to be rather unstable, undergoing an auto-decompositionon standing.
TABLE
2
Fluorination
of Substituted
Benzyl Alcohols
CsF/MsF/lB-CE-6
X
CH20H
CH2F THF
Run
X
1
4-OMe
2 3 4 5 6 7 8
3-OMe
2-OMe 4-OCH2$ 2,5-diOMe 4-Me 4-Cl I-CF3
React. time(h) 5 5 5 5 5 15 15 5
Yield ($1 80 40 23 74 35 55 72 70
Chemical shifttppm) 5.26 5.34 5.44 5.29 5.41 5.32 5.31 5.44
Coupling const (Hz) 48.6 47.7 47.9 48.6 41.1 48.1 47.7 41.0
680
Next,
we found that
heterocycles
bearing
this
method could
a N-C&OH group.
I-hydroxymethylpyrazole-4-carboxylate into
ethyl
vith
CsF (4 eq)
(Table (6)
as coupled
The formation
as a result
negligible,
(4)
as indicated
in place
with MsF (2 eq)
could
be readily
3. Potassium
with the former and the application
a total
decomposition
of the substrate
3
Fluorination
in 76% yield
fluoride
was found that
proceed
TABLE
[A]
and l&crown-6
were respectively
of CsF, and it
pyrazole-4-carboxylate
(6)
converted
(1 eq)
of the C-N bond was virtually
in Table
fluoride
ethyl
ethyl
of bis(4-ethoxycarbonylpyrazol-l-yl)methane
of cleavage
tetra-n-butylammonium procedure
For example,
I-fluoromethylpyrazole-4-carboxylate
3).
[B]
be extended to certain
(g)
and
applied
in this
the reaction
of the latter affording
did not
resulted
a mixture
of
cz> and 6.
of Ethyl l-Hydroxymethylpyrazole-4-carboxylate
CsF/18-CE-b/MsF > THF
Run 1 2 3 4
CsF
MsF
(es)
(eq)
4 4 4 2.2
2 2 2 1.2
18-CE-6 (eq) 1 1 0.3 0.3
React. temp. r.t. rfl. rfl. rfl.
React. time(h) 20 : 4
Yield(%) -5 23 0 188
e 60 zz 61
s 0 2-3 3-4 3-4
in
681
The current procedure was similarly applied to a fluorination of N-hydroxymethylphthalimide(9). but we found that bis(N-phthalimidyl)methane 0)
[C] was a major product though accompanied by a trace of
N-fluoromethylphthalimideuz). Hence, we turned to the fluorination of N-chloromethylphthalimide(II). The reaction proceeded smoothly vith CsF (1.2 eq) as modified with 18-crown-6 (0.3 eq) at room temperature and afforded I2 [D] in 76% yield (Table 4).
l_o
TABLE
4
Fluorination
of N-Chloromethylphthalimide
0 CsF/l8-CE-6 THF
r .t . 2Oh L2
RUII 1 2 3 4
CSF (eq) 4 142 1:2
18-CE-6 (eq) 1 0.3 0.3
Yield(%) L?
1:
37 64 76 21
22 5 4 0
30-35%
682
Since properties that
little
has been published
of the N-CH2F group on N-heterocycles,
the fluorine
active
to date about characteristic it
is noteworthy
atom in li: was shown to be nucleophilically
as the chlorine
atom in 11, while
enough to remain intact
I
on every
as
the one in 6 was stable
treatment
as applied
to 12.
OH/NaH , &NC"20a THF
In conclusion, fluorination
r.t.
this
of various
0
method would be of wide applicability primary
alcohols
or its
transient
to the
groups
on
N-heterocycles.
A
A typical
reaction
To a suspension (1.5
g)
procedure
for
the synthesis
of CsF (712 mg, 4.69 mmol) and molecular
in 5 ml of dry THF, was added l&crown-6
nunol) at room temperature stirring
is described
for
under stirring
of 6:
sieves
4A
(310 rug, 1.17
in nitrogen.
After
1 h. MsF (230 mg, 2.35 mmol) and 4 (200 mg, 1.18 mmol)
vas added at room temperature celite-filtration
and refluxed
of the mixture
solvent
was evaporated
acetate
solution
and ethyl
was washed vith
for
using ‘a small acetate
4 h. After amount of THF, the
was added.
water and dried
The ethyl
on anhydrous
683
sodium sulfate.
After
removal of the solvent,
chromatographed on silica obtain
the residue
gel with chloroform
was
as an eluent
154 mg (76%) of 6. mp 44-45 “C. ir(KBr):
3415,
to
1698, 1560,
1449, 1410, 1250, 1224, 1189, 1136, 1028, 992, 962, and 770 cm-l. 6 1.36(3H,
pmr(CDC13)
t,
d, J=52.1 Hz), 8.02(1H, 60.61(t),
83.18(t),
162.31 (s).
J=7.1 Hz), 4.32(2H, s),
and 8.14(1H,
92.30(t),
s).
117.80(s),
q. 3~7.1 Hz), 6.29(2I-l,
mp 239-240 “C. ir(KBr):
s),
3425,
6 1.33(6H.
7.94(2H,
peak),
1212. 951, 730, and 768 cm-l. 7.60-8.00(8H,
and
3400, 1723, 1705, 1555, 1382, 1290,
ms m/z 292(M+), 264, 247(base C m;
143.05(d),
and 127.
1248, 1231, 1029, and 764 cm-*. pmr(CX13) 4.28(4H,
cmr(CEC13) 6 14.33(q),
134.42(d),
ms III/Z 172(M+>, 144(base peak),
B 8; mp 145-146 “C. ir(KBr):
q, J=7.1 Hz), 6.02(2H,
s),
t,
J=7.1 Hz),
and 8.16(W,
s).
236, 153, and 168.
1769, 1719, 1432, 1390, 1311,
pmr(CDC13) 6 5.64(2H,
m). ms m/z 306(M+, base peak),
s),
250, 222,
and 160, 132,
and 104. D E;
mp 83-84 “C. ir(KBr):
3480,
1290, 972, 722, and 708 cm-l. and 7.6@8,10(4H, 131.69(s), peak),
1
1780, 1722, 1468, 1418, 1364, 1328,
pmr(CDC13) 6 5.77(2R,
m) . cmr(CDC13) 6 70.55(t),
134.91 (d) , 166.36(s),
d, J=52.1 Hz),
79.33(t),
and 166.46(s).
124.14(d).
ms m/z 179(W,
160, 151, 135. 132, 123, and 104.
M. Shimizu, Y. Rakahara, and H. Yoshioka,
Tetrahedron L&t..
(1985) 4207. 2
base
V. V. Aksenov. V. M. Vlasov, V. P, Fadeeva, V. S. Chertok, Chem., 24 (1985) 73.
I. Il. Moryakina, P. P. Rodionov, and G. C. Yakobson, J. Fluorine
a