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Cycloadditions of organic azides to cyclopentadienones
Tetrahedron Letters No. 29, pp 2463 - 2466, 1977. Pergemon Press. Printed in Great Britain.
CYCLOADDITIONS OF ORGANIC Alfred
Hassner,
David
AZIDES
J. Anderson
Department State
TO CYCLOPENTADIENONES1a
University
and Robert
of New York
Binghamton,
H. Reuss
of Chemistry
lb
at Binghamton
New York
13901
(Received in USA 5 Mqy 1977; received in UK for publication 8 June 1977) Organic not only
azides,
cycloadditions. for
in particular,
as precursors 2
the thermal
cycloaddition
of j_ via the azide with 2_ acting
azides
have
been
which
shown
add
We now report with
2 which
group,
the thermal
affords
that can a priori
the vinyl
thermally
in a Diels-Alder novel
with
fashion
nitrene
be predicted or the olefinic Some vinyl
2 via prior
transformation azepines 5. 3
of several
types
of organic
such as azabicycloB.3.OJoctanes,
azabicyclofi.l.O]hexanones,
and pyridones,
interest
in dipolar 2 includes
moiety
component.
to produce
cycloaddition
heterocycles
recent
partners
1 to cyclopentadienones
as the 2r- or 4a-electron
to react
bicyclop.2.1]octanones, C2.2.l]heptanones
azides
have elicited
as potential
of pathways
of vinyl
bond
azides,
but also
The multiplicity addition
double azirines
vinyl
to nitrenes
depending
as well
on the structure
to azides aza-
as azidobicyclo of the azide
sub-
strate.4 For instance, produce 1767 la -
2 (52%)
cm-l),
vinyl
together
An 88% yield
azide with
of 3a was
(1.5 eq) and 2b to stand
la_,
X:
H
lb, X: NO2 i; __)
2b in refluxing chloroform to -la reacts with a minor amount (2%) of Diels-Alder adduct 4 (ir realized
by allowing
a benzene
at 25' for 4 days.
G,
R: Me
3a_, Ar: Ph
E,
R: Et
%,
X: 0CH3
Ar: C6H4N02
3c, Ar:
2463
C6H4OCHq
solution
of
2464
No. 29
The and mass
structure
of 2 follows
spectra.
3a shows _
from
ir, H nmr,
a C=O absorption
europium
shift
studies,
13C nmr
at 1695 cm-l.
Et Ph
Downfield
shifts
Complexation
in ppm on Eu(fod)3
of the oxygen
5 with
Eu(fod)3
cially
those
causes
located
the regioisomeric to steric
and electronic
reaction,
relative
This observed case are
suggests
to 3 and
factors
in its borohydride
than
leading
Electron
shift
azide
of vinyl
attacked
with
the pathway
of starting
approximately charge
azides
with
shown
excludes sensitive
materials X speed
in the transition rate
order
state
which
we
In the latter Our
via the B-carbon.
in reaction
scheme
with
up the
6:3:1.
triazolinediones.5 system
product (espe-
This
substituents
to the relative
the unsaturated
reduction B-protons
of 1 to 2. is highly
to recovery
withdrawing
of --1b:la:lc being stabilization of a negative contrast
for the
for the y-protons.
rates
is in direct
in consonance
and
downfield
The cycloaddition
L.
azides.
for the reaction
the vinyl
larger
syn to the oxygen)
styryl
leading
in ketone &
a much
structure
B-substituted the
complexation
data
1.
Scheme By comparison, group
diazoethane
as well Phenyl
(S) reacts
to produce
tion
of B_ is not a fast
the
phenyl
presence
to tetraphenylcyclopentadienone
as at one of the double
azide
60')
2 since
adds
the bridged azide
step
slowly ketones
bonds
with
to produce
of the 2,3-dihydro
toluene
2 in ca. 70% yield.
largely
derivative
of -. 2b
upon
(no reaction
Apparently,
but is dependent
unchanged
at the carbonyl
a dihydropyrazole.6
2_ in refluxing
in the reaction
S remains
1
refluxing
Furthermore,
at
decomposi-
on the presence in toluene phenyl
in
nitrene
of
~0.29
2465
Generated
from
9b is stable photochemical this
Under
addition and
conditions
with
to the indoline
2b Ketone -* 10 upon -
at 350 nm.
to the behavior picryl
azide
to cyclopentadienone.
via oxidation
did not react
by a 1,3-shift
of 3,5_dinitrophenylazide
is analogous
these
and tributylphosphine
but rearranges
irradiation
Reaction and
nitrobenzene
at 200'
with
of sulfonyl
forms
phthalimide. *
the o-pyridone
azldes
with
fi
(33%) tetracyclone. 7
the furazan-N-oxide
2 was achieved
of N-amino
2b to give
using
ethyl
In this manner
12 Nitrene -* azidoformate at 1150 the fused
aziridines
Efforts are under-13 and -14 were formed in 64% and 100% yield, respectively. way to determine the reaction mechanisms in these transformations and the various
factors
that
influence
the pathway
chosen.
Ph
n
Et R: Me
or E+
Ar: Ph; 3,5-kh1C2)2C~Hj
oi-
2,4,6ff”02)3C6H2
-C02Et Ph
2466
No. 29
Acknowledoment This National
investigation Cancer
was
Institute,
supported
by Grant
NO. CA 19203
awarded
by the
DHEW.
REFERENCES 1.
(a) Cycloadditions N. Sartoris, in part
2.
(a) T. Sheradsky
Chem.
3076
z.
4. 5.
A. Hassner,
6.
Muller 7. 8.
Hassner,
A.
(1976);
of the Azide
pp. 373-384; 7301
Ed., 14,
were
see
7698
R. M. Cory
(b) Work
carried
S. Patai,
Ed.,
and out
of Colorado.
(1973) 775
(b) A. Hassner
D. Tang
Group,'
(b) K. H. Houk. and references
J. Sims,
therein;
Inter-
C. R. Watts,
(c) 6. L'Abbe,
(1975). J. Org.
Chem.,
39,
and D. J. Anderson,
characterized
and J.
and A. J. Thommen,
D. J. Anderson, C, 576
Keogh,
and A. Langbein,
and M. El-Chahani,
R. A. Abramovitch Sot.
95,
XXII
98,
by ir, H-nmr,
3070
E.,
(1974); 38,
mass
ibid.
2565
spectra
(1973).
and
analysis.
(a) B. Eistert 6. Fink
Sot.,
and D. J. Anderson,
(1974);
All new compounds elemental
1971,
Intern.
(a) A. Hassner 39,
Chem.
in "Chemistry
Publishers
L. Luskus,
Angew 3.
J. Amer.
at the University
science and
For paper
XXIII.
J.
Annalen.
ibid., Chem.
703,
Ber.,
and 6. N. Knaus, T. L. Gilchrist,
(1970).
Org.
Chem., 678,
104 101,
J. Chem.
4l_, 2102
78 (1964);
(1967); 3138
(b) 8. Eistert,
(c) B. Eistert,
R.
(1968).
Sot. Chem.
D. C. Horwell
(1976).
Comm.
238
and C. W. Rees,
(1974).
J. Chem.
CYCLOADDITIONS OF ORGANIC Alfred
Hassner,
David
AZIDES
J. Anderson
Department State
TO CYCLOPENTADIENONES1a
University
and Robert
of New York
Binghamton,
H. Reuss
of Chemistry
lb
at Binghamton
New York
13901
(Received in USA 5 Mqy 1977; received in UK for publication 8 June 1977) Organic not only
azides,
cycloadditions. for
in particular,
as precursors 2
the thermal
cycloaddition
of j_ via the azide with 2_ acting
azides
have
been
which
shown
add
We now report with
2 which
group,
the thermal
affords
that can a priori
the vinyl
thermally
in a Diels-Alder novel
with
fashion
nitrene
be predicted or the olefinic Some vinyl
2 via prior
transformation azepines 5. 3
of several
types
of organic
such as azabicycloB.3.OJoctanes,
azabicyclofi.l.O]hexanones,
and pyridones,
interest
in dipolar 2 includes
moiety
component.
to produce
cycloaddition
heterocycles
recent
partners
1 to cyclopentadienones
as the 2r- or 4a-electron
to react
bicyclop.2.1]octanones, C2.2.l]heptanones
azides
have elicited
as potential
of pathways
of vinyl
bond
azides,
but also
The multiplicity addition
double azirines
vinyl
to nitrenes
depending
as well
on the structure
to azides aza-
as azidobicyclo of the azide
sub-
strate.4 For instance, produce 1767 la -
2 (52%)
cm-l),
vinyl
together
An 88% yield
azide with
of 3a was
(1.5 eq) and 2b to stand
la_,
X:
H
lb, X: NO2 i; __)
2b in refluxing chloroform to -la reacts with a minor amount (2%) of Diels-Alder adduct 4 (ir realized
by allowing
a benzene
at 25' for 4 days.
G,
R: Me
3a_, Ar: Ph
E,
R: Et
%,
X: 0CH3
Ar: C6H4N02
3c, Ar:
2463
C6H4OCHq
solution
of
2464
No. 29
The and mass
structure
of 2 follows
spectra.
3a shows _
from
ir, H nmr,
a C=O absorption
europium
shift
studies,
13C nmr
at 1695 cm-l.
Et Ph
Downfield
shifts
Complexation
in ppm on Eu(fod)3
of the oxygen
5 with
Eu(fod)3
cially
those
causes
located
the regioisomeric to steric
and electronic
reaction,
relative
This observed case are
suggests
to 3 and
factors
in its borohydride
than
leading
Electron
shift
azide
of vinyl
attacked
with
the pathway
of starting
approximately charge
azides
with
shown
excludes sensitive
materials X speed
in the transition rate
order
state
which
we
In the latter Our
via the B-carbon.
in reaction
scheme
with
up the
6:3:1.
triazolinediones.5 system
product (espe-
This
substituents
to the relative
the unsaturated
reduction B-protons
of 1 to 2. is highly
to recovery
withdrawing
of --1b:la:lc being stabilization of a negative contrast
for the
for the y-protons.
rates
is in direct
in consonance
and
downfield
The cycloaddition
L.
azides.
for the reaction
the vinyl
larger
syn to the oxygen)
styryl
leading
in ketone &
a much
structure
B-substituted the
complexation
data
1.
Scheme By comparison, group
diazoethane
as well Phenyl
(S) reacts
to produce
tion
of B_ is not a fast
the
phenyl
presence
to tetraphenylcyclopentadienone
as at one of the double
azide
60')
2 since
adds
the bridged azide
step
slowly ketones
bonds
with
to produce
of the 2,3-dihydro
toluene
2 in ca. 70% yield.
largely
derivative
of -. 2b
upon
(no reaction
Apparently,
but is dependent
unchanged
at the carbonyl
a dihydropyrazole.6
2_ in refluxing
in the reaction
S remains
1
refluxing
Furthermore,
at
decomposi-
on the presence in toluene phenyl
in
nitrene
of
~0.29
2465
Generated
from
9b is stable photochemical this
Under
addition and
conditions
with
to the indoline
2b Ketone -* 10 upon -
at 350 nm.
to the behavior picryl
azide
to cyclopentadienone.
via oxidation
did not react
by a 1,3-shift
of 3,5_dinitrophenylazide
is analogous
these
and tributylphosphine
but rearranges
irradiation
Reaction and
nitrobenzene
at 200'
with
of sulfonyl
forms
phthalimide. *
the o-pyridone
azldes
with
fi
(33%) tetracyclone. 7
the furazan-N-oxide
2 was achieved
of N-amino
2b to give
using
ethyl
In this manner
12 Nitrene -* azidoformate at 1150 the fused
aziridines
Efforts are under-13 and -14 were formed in 64% and 100% yield, respectively. way to determine the reaction mechanisms in these transformations and the various
factors
that
influence
the pathway
chosen.
Ph
n
Et R: Me
or E+
Ar: Ph; 3,5-kh1C2)2C~Hj
oi-
2,4,6ff”02)3C6H2
-C02Et Ph
2466
No. 29
Acknowledoment This National
investigation Cancer
was
Institute,
supported
by Grant
NO. CA 19203
awarded
by the
DHEW.
REFERENCES 1.
(a) Cycloadditions N. Sartoris, in part
2.
(a) T. Sheradsky
Chem.
3076
z.
4. 5.
A. Hassner,
6.
Muller 7. 8.
Hassner,
A.
(1976);
of the Azide
pp. 373-384; 7301
Ed., 14,
were
see
7698
R. M. Cory
(b) Work
carried
S. Patai,
Ed.,
and out
of Colorado.
(1973) 775
(b) A. Hassner
D. Tang
Group,'
(b) K. H. Houk. and references
J. Sims,
therein;
Inter-
C. R. Watts,
(c) 6. L'Abbe,
(1975). J. Org.
Chem.,
39,
and D. J. Anderson,
characterized
and J.
and A. J. Thommen,
D. J. Anderson, C, 576
Keogh,
and A. Langbein,
and M. El-Chahani,
R. A. Abramovitch Sot.
95,
XXII
98,
by ir, H-nmr,
3070
E.,
(1974); 38,
mass
ibid.
2565
spectra
(1973).
and
analysis.
(a) B. Eistert 6. Fink
Sot.,
and D. J. Anderson,
(1974);
All new compounds elemental
1971,
Intern.
(a) A. Hassner 39,
Chem.
in "Chemistry
Publishers
L. Luskus,
Angew 3.
J. Amer.
at the University
science and
For paper
XXIII.
J.
Annalen.
ibid., Chem.
703,
Ber.,
and 6. N. Knaus, T. L. Gilchrist,
(1970).
Org.
Chem., 678,
104 101,
J. Chem.
4l_, 2102
78 (1964);
(1967); 3138
(b) 8. Eistert,
(c) B. Eistert,
R.
(1968).
Sot. Chem.
D. C. Horwell
(1976).
Comm.
238
and C. W. Rees,
(1974).
J. Chem.