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Ortho metalation directed by α-amino alkoxides. An improved synthesis of ortho-substituted aryl ketones
Tetrahedron Letters,Vol.24,No.49,pp Printed in Great Britain
ORTHO METALATION
Department
oo40-4039/83 $3.00 + .oO 01983 Pergamon Press Ltd.
5465-5468,1983
DIRECTED BY o-AMINO ALKOXIDES. AN IMPROVED OF ORTHO-SUBSTITUTED ARYL KETONES Daniel L. Comins* and Biochemistry,
of Chemistry
and Jack D. Brown Utah State University,
SYNTHESIS
Logan,
Utah 84322
Summary: Ortho-substituted aryl ketones are prepared from N-[2-(dimethylamino)ethy]-Nmethylbenzamides via ortho lithiation of intermediate a-amino alkoxides, formed in situ by addition of RLi. An ortho lithiation of N-[2-(dimethylamino)ethyl]-N-methylbenzamide is also described. Tertiary
a-amino
to a tertiary
alkoxides,
arylcarboxamide,
subsituted
aryl
thiophenesl
and furans2
reported
using
this
This
by ortho
method
works
due to their ease of method
with
(1) directly
dimethylamino)
in situ by the addition
can be ortho-lithiated
ketones.lm3
chlorobenzamide followed
formed
and reaction
group
are only
moderate.3
systems,
a more powerful
To
with
is not a strong
make
this
method
ortho directing
They
converted
aryl ketones
director,
general
alkoxide
However,
for a variety
group
in our
alkoxides.4-6
were
director
formed
in
have
been
a novel one-pot
situ
in benzene. and vigorous
ortho
For
example,
via
ortho
the
studying
It
increased when
was by
the
alkylation
alkoxides.5 addition
of
The cl-(N-methylpiperazino) metalation
1ithiation.S
be dramatically
alkoxide.8
we
a-(N-methylpiperazino)benzyl
methylpiperazide
could
laboratories
We have reported
ortho-lithiated
to effect
the a-(N,Nyields
of -2
of benzenoid
2
Recently
ortho
of RLi
is needed;
-1
alkoxides
of have
N,N-dimethyl-P-
2 via addition
and the isolated
and useful
ortho-
a-metalation
and co-workers3
an electrophile.
ortho
a-amino
Gschwend
reagent
to provide
for the directed
systems.
into ortho-substituted
lithiation
alkoxide
and alkylated
well
deprotonation.
benzenoid
of an organolithium
conditions
subsequently varying
the
alkoxide
amine
N,N,N'-trimethylethylenediamine
5465
to
group proved
benzene,
reflux)
a-amino
aldehydes
intermediate
aldehydes
discovered
of
of aromatic The
aryl
(3 n-BuLi,
chemistry
lithium
was
of used
N-
to be a weak were
that the metalation
component
via
o-amino
needed rate
the a-amino as the
amine
5466
component, as shown
benzaldehyde below.
TMEDA-like
could be ortho-metalated-silylated
The metalation
assisted
rate
increase
at low temperature
is undoubtedly
in high yield
due to an intramolecular
metalation.6
THF
We have synthesis table.
82% (one-pot)
applied
the
diamine
of ortho-substituted The yields
are high
concept
to the Gronowitz-Gschwend
aryl ketones
as shown
and the method
below.
is clearly
procedure
The results
superior
for the
are given
to the original
in the version
Li I
1. E
+
4 q
2. 3 c-BuLi
q
2. H30+ 4
3 using
N, N-dimethylbenzamides.
(methylthio)acetophenone temperature
to preventbenzyne
chlorobenzamide desired
gave
is most
8), where
evident
ortho
3-chloroacetophenone
(entry
lithiation
(80%) and only
hydrolyzed
ortho
lithiation
The
group
main
results.
is its resistance
with
6N HCl(reflux)
should compliment
This of course
of
the
to hydrolysis.g
(inverse Fund, administered
acid
and work
Me1
Aknowledgements.
support
by the American
(cl%)
analogous
initially amide
of the
attack by
as an ortho
new ortho-directing
toward
by Beak
metalation
the amino
This
does
to the ortho
introduced
(a). lo
is in progress
amide 5 is easily group
that goal.
, 5
of this work Chemical
nucleophilic
In contrast,
addition)15 Financial
N,N-dimethyl-3-
a trace
at -78°C (THF) addition
is directly
methodology
N,N-diethyl
to g-toluic
Beak's methodology,
undergo
with -see-BuLi/TMEDA
a powerful
disadvantage
of 3-chloro-2must occur at low
9).
however,
of N,N-diethylbenzamides,
Brown.8
directing
as demonstrated,
synthesis
Under the same conditions,
formation.7
product
in the
lithiation-alkylation
N-[2-(dimethylamino)ethyll-N-methylbenzamides reagents
not occur and
and
mainly
ortho-substituted
The lithium
This
(entry
55%
by the donors
Society,
!? 81% of the Petroleum
is gratefully
acknowledged.
Research
5467
Table Synthesis
of Ortho-Substituted Aryl Ketones From Tertiary Benzamides ____________________~~~~~~~-----------------------------~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~_~__
Entry
Amide
Reaction Productb Yieldc mp,"C E Conditionsa (lit. mp) % _______________________~~_~_~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~_~_~~_~__________________ 1
N,N-dimethyl benzamide
1) 1.5 MeLi, PhH, 0", 2) 3 n-BuLi, RT, 5h
l/2 h
Me1
g-methylacetophenone
2
j,X=H
1) 1.5 MeLi, PhH, 0", 2) 3 fl-BuLi, RT, 5h
l/2 h
Me1
g-methylacetophenone
33d
w-m
[i8)d
2,4-DNP 160-162 (161-162)11
3
&X=H
1) 1.1 n-BuLi, PhH, 0", l/2 h 2) 3 I-BuLi, RT, 24h
Me1
c-methylvalerophenone
4
J,X=H
1) 1.1 n-BuLi, PhH, 0", l/2 h 2) 3 n-BuLi, RT, 24h
MeSSMe
o-(methylthio)-77 valerophenone
Me1
o-methylbenzophenone
o-(methylthio)-85 chloroacetophenone
5
&X=H
1) 1.5 PhLi, PhH, O", 2) 3 fl-BuLi, RT, 12h
6
3, X = p-Cl
1) 1.5 MeLi, THF -2O", 3/4 h 2) 3 fi-BuLi, -20b, 4h
MeSSMe
l/2 h
55
2,4-DNP 75-77 (76-78)'l
2,4-DNP 130-132,
85
62-6 3 (62)
7
3, x = p-Cl
1) 1.5 MeLI, THF, -2O", 3/4 h 2) 3 n-BuLi, -2O", 4h
Me1
o-methyl-e87 chloroacetophenone
oxime 68-6 73 (69)
8
3, X = m-Cl
1) 1.5 MeLi, THF, -78', 3/4 h 2) 3 fi-BuLi, -78", 7h
MeSSMe
o-(methylthio)-63 fi-chloroacetophenone
2,4-DNP 107-108,
1 2
MeSSMe
o-(methylthio)ld ij-chloroacetophenone
-_-
___
9 N,N-dimethyl-mchlorobenzamiae
-78", 3/4 h
10 N,N-dimethyl-emethoxybenzamide
1) 1.5 MeLi, PhH, RT, 4h 2) 3 E-BuLi, THF, -2O", 24h,
Me1
o-methyl-e2d methoxyacetophenone
11
1) 1.5 MeLi, PhH, RT, 4h 2) 3 E-BuLi, THF, -2O", 24h
Me1
o-methyl-e83 methoxyacetophenone
1, X =p-OMe
b
b
semicarbazone
---______________-__~~~~~~~~~~-----~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~_~~__~_ aReactions were performed on a 3-mmol scale. THF was added to the reaction mixtures in benzene prior to cooling to -42°C and adding the electrophile (6 equiv). The workup consisted of pouring the reaction mixture into stirred cold 10% aqueous HCl followed by extraction with ether.
5468
bAll products gave the expected IR and 'H NMR spectra. New products, from entries 4 and 8, gave satisfactory analytical data. 'Yields are for isolated, pure, material obtained from preparative layer chromatography (silica gel, acetone-hexanes). dGC yield. References and Notes. 1.
U. Michael and S. Gronowitz, Acta. Chem.Scand.,_,22 1353 (1968); V. P. Litvinov, Ya. L. Gol'dfarb, V. V. Zelentosovm.anova, and N. N. Pewtukhova, Khim. Geterotsikl. Soedin., 486 (1975); V. P. Litvinov, T. V. Schchedningskaya, P. A. Konstantinov, and Ya. L. Gol'dfarb, Khim. Geterotsikl. Soedin., 492 (1975).
2.
S. Gronowitz, _-*-, Ark. Kemi
3.
L. Barsky, H. W. Gschwend, J. McKenna, and H. R. Rodriquez, J. Org. Chem., 41, 3651 (1976).
4.
D. L. Comins, and W. Dernell, Tetrahedron &., 4213 (1981). Brown, Tetrahedron &,
5.
D. L. Comins,
6.
D. L. Comins and J. D. Brown, J.Drg. Chem., in press. This paper was presented in part at a recent ACS meeting. D. L.Comins, J. D. Brown, and N. B. Mantlo, ORGN, 117, 185th National Meeting of the American Chemical Society, Seattle, Washington, March 20-25, 1983.
7.
H. Gilman and R. D. Gorsich, J. Am. Chem.&., 23 2091(1982). Rieker, Tetrahedron m., _,
8.
P. Beak and R. A. Brown, J. Orq. Chem., 42, 1823 (1977).
9.
For a review on directed lithiation of aromatic tertiary amides, see P. Beak and V. Snieckus, __-.)-) Act. Chem. Res 15 306 (1982).
32 283 (1970).
1085 (1981); D. L. Comins and J. D.
J. D. Brown, and N. B. Mantlo, Tetrahedron w.,
3979 (1982).
7B, 2217 (1956); A. I. Meyers and W.
10. Hydrolysis of N,N-diethyl-g-methylbenzamidedid not occur under these conditions. 11. B. Cazes and S. Julia, Tetrahedron, 35, 2655 (1979). 54 12. P. R. Austin and J. R. Johnson, J. Am. Chem. Sot., _, 13. J. Claus, J * Prak- Chem -s_s2
647 (1932).
43 (1892).
46 14. C. R. Noller and R. Adams, J. Am. Chem. Sot., _,
1889 (1924).
15. The amino amide was added to -set-BuLi/TMEDA in THF at -78°C. (Received
in USA 9 September
1983)
ORTHO METALATION
Department
oo40-4039/83 $3.00 + .oO 01983 Pergamon Press Ltd.
5465-5468,1983
DIRECTED BY o-AMINO ALKOXIDES. AN IMPROVED OF ORTHO-SUBSTITUTED ARYL KETONES Daniel L. Comins* and Biochemistry,
of Chemistry
and Jack D. Brown Utah State University,
SYNTHESIS
Logan,
Utah 84322
Summary: Ortho-substituted aryl ketones are prepared from N-[2-(dimethylamino)ethy]-Nmethylbenzamides via ortho lithiation of intermediate a-amino alkoxides, formed in situ by addition of RLi. An ortho lithiation of N-[2-(dimethylamino)ethyl]-N-methylbenzamide is also described. Tertiary
a-amino
to a tertiary
alkoxides,
arylcarboxamide,
subsituted
aryl
thiophenesl
and furans2
reported
using
this
This
by ortho
method
works
due to their ease of method
with
(1) directly
dimethylamino)
in situ by the addition
can be ortho-lithiated
ketones.lm3
chlorobenzamide followed
formed
and reaction
group
are only
moderate.3
systems,
a more powerful
To
with
is not a strong
make
this
method
ortho directing
They
converted
aryl ketones
director,
general
alkoxide
However,
for a variety
group
in our
alkoxides.4-6
were
director
formed
in
have
been
a novel one-pot
situ
in benzene. and vigorous
ortho
For
example,
via
ortho
the
studying
It
increased when
was by
the
alkylation
alkoxides.5 addition
of
The cl-(N-methylpiperazino) metalation
1ithiation.S
be dramatically
alkoxide.8
we
a-(N-methylpiperazino)benzyl
methylpiperazide
could
laboratories
We have reported
ortho-lithiated
to effect
the a-(N,Nyields
of -2
of benzenoid
2
Recently
ortho
of RLi
is needed;
-1
alkoxides
of have
N,N-dimethyl-P-
2 via addition
and the isolated
and useful
ortho-
a-metalation
and co-workers3
an electrophile.
ortho
a-amino
Gschwend
reagent
to provide
for the directed
systems.
into ortho-substituted
lithiation
alkoxide
and alkylated
well
deprotonation.
benzenoid
of an organolithium
conditions
subsequently varying
the
alkoxide
amine
N,N,N'-trimethylethylenediamine
5465
to
group proved
benzene,
reflux)
a-amino
aldehydes
intermediate
aldehydes
discovered
of
of aromatic The
aryl
(3 n-BuLi,
chemistry
lithium
was
of used
N-
to be a weak were
that the metalation
component
via
o-amino
needed rate
the a-amino as the
amine
5466
component, as shown
benzaldehyde below.
TMEDA-like
could be ortho-metalated-silylated
The metalation
assisted
rate
increase
at low temperature
is undoubtedly
in high yield
due to an intramolecular
metalation.6
THF
We have synthesis table.
82% (one-pot)
applied
the
diamine
of ortho-substituted The yields
are high
concept
to the Gronowitz-Gschwend
aryl ketones
as shown
and the method
below.
is clearly
procedure
The results
superior
for the
are given
to the original
in the version
Li I
1. E
+
4 q
2. 3 c-BuLi
q
2. H30+ 4
3 using
N, N-dimethylbenzamides.
(methylthio)acetophenone temperature
to preventbenzyne
chlorobenzamide desired
gave
is most
8), where
evident
ortho
3-chloroacetophenone
(entry
lithiation
(80%) and only
hydrolyzed
ortho
lithiation
The
group
main
results.
is its resistance
with
6N HCl(reflux)
should compliment
This of course
of
the
to hydrolysis.g
(inverse Fund, administered
acid
and work
Me1
Aknowledgements.
support
by the American
(cl%)
analogous
initially amide
of the
attack by
as an ortho
new ortho-directing
toward
by Beak
metalation
the amino
This
does
to the ortho
introduced
(a). lo
is in progress
amide 5 is easily group
that goal.
, 5
of this work Chemical
nucleophilic
In contrast,
addition)15 Financial
N,N-dimethyl-3-
a trace
at -78°C (THF) addition
is directly
methodology
N,N-diethyl
to g-toluic
Beak's methodology,
undergo
with -see-BuLi/TMEDA
a powerful
disadvantage
of 3-chloro-2must occur at low
9).
however,
of N,N-diethylbenzamides,
Brown.8
directing
as demonstrated,
synthesis
Under the same conditions,
formation.7
product
in the
lithiation-alkylation
N-[2-(dimethylamino)ethyll-N-methylbenzamides reagents
not occur and
and
mainly
ortho-substituted
The lithium
This
(entry
55%
by the donors
Society,
!? 81% of the Petroleum
is gratefully
acknowledged.
Research
5467
Table Synthesis
of Ortho-Substituted Aryl Ketones From Tertiary Benzamides ____________________~~~~~~~-----------------------------~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~_~__
Entry
Amide
Reaction Productb Yieldc mp,"C E Conditionsa (lit. mp) % _______________________~~_~_~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~_~_~~_~__________________ 1
N,N-dimethyl benzamide
1) 1.5 MeLi, PhH, 0", 2) 3 n-BuLi, RT, 5h
l/2 h
Me1
g-methylacetophenone
2
j,X=H
1) 1.5 MeLi, PhH, 0", 2) 3 fl-BuLi, RT, 5h
l/2 h
Me1
g-methylacetophenone
33d
w-m
[i8)d
2,4-DNP 160-162 (161-162)11
3
&X=H
1) 1.1 n-BuLi, PhH, 0", l/2 h 2) 3 I-BuLi, RT, 24h
Me1
c-methylvalerophenone
4
J,X=H
1) 1.1 n-BuLi, PhH, 0", l/2 h 2) 3 n-BuLi, RT, 24h
MeSSMe
o-(methylthio)-77 valerophenone
Me1
o-methylbenzophenone
o-(methylthio)-85 chloroacetophenone
5
&X=H
1) 1.5 PhLi, PhH, O", 2) 3 fl-BuLi, RT, 12h
6
3, X = p-Cl
1) 1.5 MeLi, THF -2O", 3/4 h 2) 3 fi-BuLi, -20b, 4h
MeSSMe
l/2 h
55
2,4-DNP 75-77 (76-78)'l
2,4-DNP 130-132,
85
62-6 3 (62)
7
3, x = p-Cl
1) 1.5 MeLI, THF, -2O", 3/4 h 2) 3 n-BuLi, -2O", 4h
Me1
o-methyl-e87 chloroacetophenone
oxime 68-6 73 (69)
8
3, X = m-Cl
1) 1.5 MeLi, THF, -78', 3/4 h 2) 3 fi-BuLi, -78", 7h
MeSSMe
o-(methylthio)-63 fi-chloroacetophenone
2,4-DNP 107-108,
1 2
MeSSMe
o-(methylthio)ld ij-chloroacetophenone
-_-
___
9 N,N-dimethyl-mchlorobenzamiae
-78", 3/4 h
10 N,N-dimethyl-emethoxybenzamide
1) 1.5 MeLi, PhH, RT, 4h 2) 3 E-BuLi, THF, -2O", 24h,
Me1
o-methyl-e2d methoxyacetophenone
11
1) 1.5 MeLi, PhH, RT, 4h 2) 3 E-BuLi, THF, -2O", 24h
Me1
o-methyl-e83 methoxyacetophenone
1, X =p-OMe
b
b
semicarbazone
---______________-__~~~~~~~~~~-----~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~_~~__~_ aReactions were performed on a 3-mmol scale. THF was added to the reaction mixtures in benzene prior to cooling to -42°C and adding the electrophile (6 equiv). The workup consisted of pouring the reaction mixture into stirred cold 10% aqueous HCl followed by extraction with ether.
5468
bAll products gave the expected IR and 'H NMR spectra. New products, from entries 4 and 8, gave satisfactory analytical data. 'Yields are for isolated, pure, material obtained from preparative layer chromatography (silica gel, acetone-hexanes). dGC yield. References and Notes. 1.
U. Michael and S. Gronowitz, Acta. Chem.Scand.,_,22 1353 (1968); V. P. Litvinov, Ya. L. Gol'dfarb, V. V. Zelentosovm.anova, and N. N. Pewtukhova, Khim. Geterotsikl. Soedin., 486 (1975); V. P. Litvinov, T. V. Schchedningskaya, P. A. Konstantinov, and Ya. L. Gol'dfarb, Khim. Geterotsikl. Soedin., 492 (1975).
2.
S. Gronowitz, _-*-, Ark. Kemi
3.
L. Barsky, H. W. Gschwend, J. McKenna, and H. R. Rodriquez, J. Org. Chem., 41, 3651 (1976).
4.
D. L. Comins, and W. Dernell, Tetrahedron &., 4213 (1981). Brown, Tetrahedron &,
5.
D. L. Comins,
6.
D. L. Comins and J. D. Brown, J.Drg. Chem., in press. This paper was presented in part at a recent ACS meeting. D. L.Comins, J. D. Brown, and N. B. Mantlo, ORGN, 117, 185th National Meeting of the American Chemical Society, Seattle, Washington, March 20-25, 1983.
7.
H. Gilman and R. D. Gorsich, J. Am. Chem.&., 23 2091(1982). Rieker, Tetrahedron m., _,
8.
P. Beak and R. A. Brown, J. Orq. Chem., 42, 1823 (1977).
9.
For a review on directed lithiation of aromatic tertiary amides, see P. Beak and V. Snieckus, __-.)-) Act. Chem. Res 15 306 (1982).
32 283 (1970).
1085 (1981); D. L. Comins and J. D.
J. D. Brown, and N. B. Mantlo, Tetrahedron w.,
3979 (1982).
7B, 2217 (1956); A. I. Meyers and W.
10. Hydrolysis of N,N-diethyl-g-methylbenzamidedid not occur under these conditions. 11. B. Cazes and S. Julia, Tetrahedron, 35, 2655 (1979). 54 12. P. R. Austin and J. R. Johnson, J. Am. Chem. Sot., _, 13. J. Claus, J * Prak- Chem -s_s2
647 (1932).
43 (1892).
46 14. C. R. Noller and R. Adams, J. Am. Chem. Sot., _,
1889 (1924).
15. The amino amide was added to -set-BuLi/TMEDA in THF at -78°C. (Received
in USA 9 September
1983)