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Cyclopropanation of C60 via a fischer carbene complex
Tetrahedron Letters, Vol. 35. No. 51. pp. 9529-9532. 1994 Elsevia Science Ltd printed in GreatBritain (lo4&4039/94 $7.ooto.00
Pergamon 0040-4039(94)02208-9
Cyclopropanation of Cfjo Via a Fischer Carbene Complex Craig A. Merlic* and Holly D. Bendorf Department of Chemistry and Biochemistry University of California, Los Angeles, California 90024-1569
Absbvact: A new method for the preparation of methanqfUlerenes is demonstrated by the formation of I ,2-methyl(methoxymethano)fullerene-i&3
by the thermal reaction of C60 with [methyl(methoxy-
met~le~)]~~~~e)lpentacarbonylchromium.
In the quest to prepare and study derivatives of C&n, the methanofullerenes have become the most studied class of &-derived
compounds. t The methanofullerenes are quite stable and have shown promise in
applications in fields as diverse as material science and medicine. Wudl reported the synthesis of precursors to ‘pearl-necklace” polymers2 and Rubin recently synthesized ethynyl-substituted methanofullerenes for use in the preparation of macmc yclic and polymeric carbon allotropes3 Interest in the potential medical applications of fullemnes has spurred research into the preparation of water soluble methanofullerene derivatives. A water soluble methanofullerene prepared by Wudl and coworkers has been shown to inhibit HIV-l protease.
There
are several methods for the preparation of methanofullerenes. The most common is via a [3+2] cycloaddition of diazo compounds with f&u to yield intermediate pyrazolines which thermally extrude nitrogen to produce the methanofullerenes5 and has been used to synthesize a series of aryl- and ester-substituted derivatives.2>6 Strategies
involving
generation
of free carbenes
have also been employed
in the synthesis
of
methanofullerenes. Thermal decomposition of diazirines in the presence of C!+johas been utilized to prepare a glucose-derived methanofullerene7 and a chloro-substituted methanoful1erene.a Dichlommethanofulleren~ and dimethoxymethanofuRerenelo have also been prepamd by the addition of free carbenes. A “carbene-free’ methodology for the preparation of methanofullerenes involves the addition of bmmomalonate anions to Cijo followed by intramolecular substitution of the bromide, but this method is limited in scope.11 We envisioned a new route to methanofullerenes
using the well-documented
chemistry of Fischer carbene complexes. 12 Cyclopropanation of electron-deficient
cyclopropanation
olefins by chromium
carbenes is sensitive to the steric environment about the alkene and is generally only effective for monosubstituted substrates. However, the steric effects of the tetrasubstituted double bonds in C&Jwere expected
9529
9530
to be countred by the pyramidalized hence x-acidity,
of i&~.t3
nature of the double bonds combined with the high electrophilicity,
We report herein successful cyc~~ropa~tion
complex which provides another route to methanofullerenes Much of the reported c~mium these cornFunds sot react with &
were tested for @
~clop~anatio~
cyclopropanation,
so
t4J5 While the phenyl methoxy carbene complex did the more reactive methyl methoxy carbine UIXI@SC by flash chromatography
gave the desired 1,2-dihydn>-1~-m~thyl(methoxymethano)-full~n~~ junction.
has used fphenyl-
Rewtion d two quivaients of methyl methoxy carlme complex with QQ in vigorously
reacted successfully.
refluxing benzene for 72 h with subsequent purification meth~ofulle~ne
chemistry
and [~yl(me~~~~yiene)]~nt~~~nylchromium,
under a variety of themal conditions,
and
carbene
which excludes free carbene intermediates.
cone-~diat~
~methoxymethylene)lpentaearbonyichmm~u~
of C&J by a chromium
(98:2 hexane/ethyl
acetate}
as a brown solid (equation).
product was obtained as a single isomer resulting f&m cyclopropanatibn
The
of a 6,6 ring
‘Ihe presence of 26 signals (3 of greater intensity) in the fullerene region of the 13C NMR confirmed
the Cs symmetry of the pmduct (see Figure). 16 The ~5o_sp3 carbon resonance is at 83 ppm, the mcthanobridge carbon is obsezwzd at 73 ppm and the methyl and methoxy casbons are observed at 44 and 55 ppm, respectiwely. Two singlets‘ in the IH NMR at 3.65 and 2.28 ppm correspond protons. ritzy
The methanofullcrene
product
cBn be consistently
to the methoxy and methyl
obtained in 20% yield, however,thk
yield is not
and yields atrove 50% were achieved on multiple occasions.
Benzene C66
+
rMlJX
M
8
Carbeae derivatives of Cm can exist as isumeric ~t~anofuller~ne fuller&i
(methanoannulene)
fuller&d Structure is predhed confirm
this prediction.t3
methanofullerene
5,6 ring junction
6,6 ring junction
adducts. 17 For the unsubstituted
fo be the more stable isomer by ,0.34 kCd&kd,6a
derivative,
structure is the more stable isomer.
C61H2, the
and equilibration
for substituted derivatives, PM3 ealcuiations
However,
adducts and
These findings are in excellent
studies
predict
that the
agreement
with the
observation that the substitbted fulleroid isomers can he converted to methanofukrene isomers under thermal conditi~s.~,6b~t7
The ~than~ful~~ne
shifts of the carbons methanofullerene
dimctiy
and the fulleroid isomers are easily distinguish
attached
to the methano-bridge.
6b The sp3 hybridized
by the 1% NhSR carbons of the
isomers are observed between 70 and 90 ppm while the sp2 carbons attached to the methane-
bridge in the fulleroid isomers ~TGobserved between 130 and 150 ppm The observation of a signal at 83 ppm in the 1% NMR assigned~oo the ~-sp3 as a methanofullerene.
carbons definitively
This result is in accord with the experimentally
derivatives to exist as the methanofullerene isomer is not obmecl,
identifies the merhyl(me~ox~thano)fullemne
isomer rather than the full&d
observed preference for substituted isomer.wb
Although the fuller&d
it may have been formed during the course of the reaction since the reaction conditions
a~ sufficient K, induce its isomerization to the more stable methanofullerene
isomer.
9531
Successful compared
cyclopropanati~n
to the conditions
unencumbered it becomes
high electron-af%nity
for the reaction
of chromium
3-6 h)t4 and with more substituted,
of the cyclopmpanation
alkenes
co&ination
of &
reflux
carbenes
for 3 to 4 days. ,When with activated,
sterically
activated alkenes (100-l lO.C, 10-+I h),lS nature of the double bonds as welt as the
is believed
ruaction
to bc analogous
to that proposed
for
loss of a CO with free carbenes .*2.19 Thermally-induced This step is sensitive to the steric chromium ccmpkx.
and does not involve
of Qo generates an 7$-&t
nature of the alhenc sWatrate, but Q~J is an cxcelknt
org~ometallic
benzene
of C& which accounts for the modest yield in the C&u cyc~
The mechanism
coordination
chemistry, 20 and this electronic
cyclopropanation reaction. Formal [2+2] cycloaddition elimination
a vigorous
is only partially countered by the pyramidal&d
double bonds of m
and tkctronic
required
that C!eo is a sluggjsh substrate. The low reactivity of the unactivated tetrasubstitttted
apparent
subsequent
necessary
alkencs (WC,
electron-deficient
of Qo
%-acceptor, as is well-documented’by
effect is potentkly
its
crucial to the success of the
produces a metaUacyclobutane
from which reductive
yields the methanofirlkrene.
In conclusion, as a potentially
the cyclopropa~tion
of C!eu by a Fischer chromium
general route to mcthanofullerenes.
Overall, the oxygen
ca&ne
complex has been realii
stabilized
carbcne complexes
are
hkely to be of specific interest due to their ease of preparation and the pmence of the ether functionality which provides
a handle for further functionalixation
of the methanofulkrenes.
such as the more reactive molybdcnntn and non-hetematom readily with C&2’
stabii
are expected tc react
Studies on thcsc fronts are in progress.
i40
Figure. Fulkrene
Other Fischer carbene complexes
carbene complexes
138
region of the 13C Nh4R of 1,2-met.byl(methoxymethano)fullemne_CM
136
9532
Acknowledgement: research. References ::
Z:
2: 7. 8. 9. 10. 11. 12.
13. 14_ 15. 16.
17. 18. 19. 20. 21.
We thank the National
Science
Foundation
(CHE-9257081)
for support
of this
and Notes:
Taylor, R; Walton, D. R. M. Nature l!J95,363,685. Suzuki, T.; Li, Q.; Khcmani, K. C.; Wudl. F.; Almarsson, 0. Science 1991,254, 1186. An, Y. Z.; Rubin, Y.; Schaller, C.; McEIvany, S. W. J. Org. C/tern. 1998,59,2927. a) Sijbcsma, R.; Srdanov, G.; Wudl, F.; Castoro, J. A.; Wilkins, C.; Friedman, S. H.; DeCamp, D. L,; Kenyon, G. L. J. Am. Chem. Sot. 1993, 115, 6510. b} Friedman, S. H.; DeCamp, D. L.; Sijbesma, R.; Srdanov, G.; Wudl, F.; Kenyon, G. L. J. Am. Chem. Sot. 1993, IIS, 6506. WudI, F. Act. Chem. Rev. 1992.25, 157. a) Diederich, F.; Isaacs, L.; Philp, D. /. C/zem. Sot., Perkirr Trans. 2 1994, 391. b) Isaacs, L.; Wehrsig, A.; Diderich, F.H&. Chirn. AC~U1993,76,1231. c) Suzuki, T.; Li, Q.; Khcmani, K. C.; Wudl, F. J. Am. Chem. Sac. 1992,114, 7300. d) Osterodt. FL; Nieger, M,; Windscheif, P. M.; Vogtle, E Chem. Ber. 1993,126. 2331. Vasella. A.: Uhlmann, P.; Waldcaff, C. A. A.; Diederich, F.; Thilgen, C. Angew. Chern. 1~. Ed. Engl. 1992,31,1388. Komatsu. K.; Kagayarna, A.; Murata, Y.; Sugita, N.; Kobayashi, K.; Nagaae, S.; Wan, T. S. M. Chem. Lett. 1993, 2163. Tsuda, M.; Ishida, T.: Nogami, T.; Kurono, S.; Ohashi, M. Tetrahedron Lert. 1993,34, 6911. Isaacs, L.; Diederich, F. Helv. Chim. Acta 1993,76. 2454. a) Bingel, C. Chem. Ber. 1993,126, 1957. b) Hirsch, A.; Lamparth, I.; Karfunkel, H. R. Angew. Chem. Int. Ed. Engl. 1994,33,437. a) Wulff, W. D. In Comprehensive Organic Synthesis; Trost, B. M., Fleming, I., &Is.; Pcrgamon Press: New York, 1990, Vol. 5. b) D&z, K. H.; Fischer, I%; Hofmann, P.; Kreissel, F. R.; Schubert, U.; Weiss, K. Transhiun Metal Carbene Complexes; Verlag Chemie: Deerfield Beach, FL, 1983. c) Brookhart, M.; Studebaker, W. B. Chem. Rev. 1987,87, 411. d) Collman, J. P.; Hegedus. L. S.; Norton, J. R,; Finke, R. G. Principles and Applications ofOrganoiransition Metal Chertdst~ University Science Books: Mill Valley, Calif., 1987. e) Hegedus, L. S. Transition Metals in the Syntkesis of Complex Organic Molecules University Science Books: Mill Valley, Calif., 1994. Haddon, R. C. Act. C/tern. Res. 1992,25, 127, and references therein. a) Wienand, A.; Reissig, H.U. Tetrahedron L&t. 1988,29, 2315. b) Fischer, E. 0.; D&z, K. H. Chem. Ber. 1970, 203, 1273. a) Biichert, M.; Reissi H. U. Tetrahedron Letr. 1938,29, 2319. b) Herndon, J. W.; Turner, S. U. Tetrahedron L&t. 198 i ,34,4771. c) D&z, K. H.; Fischer, E. 0. Chem. Ber. 1972,105, 1356. IR (KBr pellet): 2962, 2929,2850, 1736, 1504, 1458, 1425, 1378, 1259, 1219, 1160, 1099, 1073, 1034,801, 523, 430, 420. IH NMR (360 MHz, CS&jD6) 6: 2.28 (II-l, s), 3.65 (IH, s). 13C NMR (90.6 MH~, CS2/C&j, 0.01 M Cr(acac)j) 6: 146.45, 146.19, 145.90, 145.60, 145.38, 145.34, 145.30, 145.22, 145.08, 145.06, 144.85, 144.52, 144.43, 143.98, 143.80, 143.53. 143.29, 143.24, 142.89, 142.44, 142.40, 142.36, 141.42, 141.35, 138.44, 137.06, 83.02, 73.81, 55.83, 14.47. MS (FAB): 779 (50, M+l), 763(28, M-CH3), 747(28, M-OCH3). 721(62, &+I). Prato, M,; Lucchini, V.; Maggini, M.; Stimpfl, E.; Scorrano, CL; Eiennann, M.; Suzuki, T.; Wudi, F. J. Am. Chem. Sot. 1990,115, 8479. a) Suzuki, T.; Li, Q_; Khemani, K. C.; Wudl, F. J. Am. Chem. Sot. 1992, 114, 7301. b) Smith, A. B., III; Strongin, R. M.; Brand, L.; Furst, G. T.; Romanow, W. J. J. Am. Chem. SOC. 1993,115, 5829. IXtz, K. H. Angew. Chem. fnr. Ed. Engl. 1984,23, 587. a) Fagan, P. J.; Calabrese, J. C.; Malone, B. Act. Chem. Res. 1992,25, 134. b) Fagan, P. I.; Chase, B.; Calabrcse, J. C.; Dixon, D. A.; Harlow, R.; l&sic, P. J.; Maltsuzawa, N.; Tebbe, F. N.; Thorn, D. L.; Wasserman, E. Carbon 1992.30, 1213. a) Harvey, D, F.; Brown, M. F. Tecruhedron Left. 1990,3I, 2529, b) Harvey, D. F.; Lund, K. P. J. Am. Chem. Sot. f991,II3, 8916.
(Received in USA 6 October 1994; accepted 3 November 1994)
Pergamon 0040-4039(94)02208-9
Cyclopropanation of Cfjo Via a Fischer Carbene Complex Craig A. Merlic* and Holly D. Bendorf Department of Chemistry and Biochemistry University of California, Los Angeles, California 90024-1569
Absbvact: A new method for the preparation of methanqfUlerenes is demonstrated by the formation of I ,2-methyl(methoxymethano)fullerene-i&3
by the thermal reaction of C60 with [methyl(methoxy-
met~le~)]~~~~e)lpentacarbonylchromium.
In the quest to prepare and study derivatives of C&n, the methanofullerenes have become the most studied class of &-derived
compounds. t The methanofullerenes are quite stable and have shown promise in
applications in fields as diverse as material science and medicine. Wudl reported the synthesis of precursors to ‘pearl-necklace” polymers2 and Rubin recently synthesized ethynyl-substituted methanofullerenes for use in the preparation of macmc yclic and polymeric carbon allotropes3 Interest in the potential medical applications of fullemnes has spurred research into the preparation of water soluble methanofullerene derivatives. A water soluble methanofullerene prepared by Wudl and coworkers has been shown to inhibit HIV-l protease.
There
are several methods for the preparation of methanofullerenes. The most common is via a [3+2] cycloaddition of diazo compounds with f&u to yield intermediate pyrazolines which thermally extrude nitrogen to produce the methanofullerenes5 and has been used to synthesize a series of aryl- and ester-substituted derivatives.2>6 Strategies
involving
generation
of free carbenes
have also been employed
in the synthesis
of
methanofullerenes. Thermal decomposition of diazirines in the presence of C!+johas been utilized to prepare a glucose-derived methanofullerene7 and a chloro-substituted methanoful1erene.a Dichlommethanofulleren~ and dimethoxymethanofuRerenelo have also been prepamd by the addition of free carbenes. A “carbene-free’ methodology for the preparation of methanofullerenes involves the addition of bmmomalonate anions to Cijo followed by intramolecular substitution of the bromide, but this method is limited in scope.11 We envisioned a new route to methanofullerenes
using the well-documented
chemistry of Fischer carbene complexes. 12 Cyclopropanation of electron-deficient
cyclopropanation
olefins by chromium
carbenes is sensitive to the steric environment about the alkene and is generally only effective for monosubstituted substrates. However, the steric effects of the tetrasubstituted double bonds in C&Jwere expected
9529
9530
to be countred by the pyramidalized hence x-acidity,
of i&~.t3
nature of the double bonds combined with the high electrophilicity,
We report herein successful cyc~~ropa~tion
complex which provides another route to methanofullerenes Much of the reported c~mium these cornFunds sot react with &
were tested for @
~clop~anatio~
cyclopropanation,
so
t4J5 While the phenyl methoxy carbene complex did the more reactive methyl methoxy carbine UIXI@SC by flash chromatography
gave the desired 1,2-dihydn>-1~-m~thyl(methoxymethano)-full~n~~ junction.
has used fphenyl-
Rewtion d two quivaients of methyl methoxy carlme complex with QQ in vigorously
reacted successfully.
refluxing benzene for 72 h with subsequent purification meth~ofulle~ne
chemistry
and [~yl(me~~~~yiene)]~nt~~~nylchromium,
under a variety of themal conditions,
and
carbene
which excludes free carbene intermediates.
cone-~diat~
~methoxymethylene)lpentaearbonyichmm~u~
of C&J by a chromium
(98:2 hexane/ethyl
acetate}
as a brown solid (equation).
product was obtained as a single isomer resulting f&m cyclopropanatibn
The
of a 6,6 ring
‘Ihe presence of 26 signals (3 of greater intensity) in the fullerene region of the 13C NMR confirmed
the Cs symmetry of the pmduct (see Figure). 16 The ~5o_sp3 carbon resonance is at 83 ppm, the mcthanobridge carbon is obsezwzd at 73 ppm and the methyl and methoxy casbons are observed at 44 and 55 ppm, respectiwely. Two singlets‘ in the IH NMR at 3.65 and 2.28 ppm correspond protons. ritzy
The methanofullcrene
product
cBn be consistently
to the methoxy and methyl
obtained in 20% yield, however,thk
yield is not
and yields atrove 50% were achieved on multiple occasions.
Benzene C66
+
rMlJX
M
8
Carbeae derivatives of Cm can exist as isumeric ~t~anofuller~ne fuller&i
(methanoannulene)
fuller&d Structure is predhed confirm
this prediction.t3
methanofullerene
5,6 ring junction
6,6 ring junction
adducts. 17 For the unsubstituted
fo be the more stable isomer by ,0.34 kCd&kd,6a
derivative,
structure is the more stable isomer.
C61H2, the
and equilibration
for substituted derivatives, PM3 ealcuiations
However,
adducts and
These findings are in excellent
studies
predict
that the
agreement
with the
observation that the substitbted fulleroid isomers can he converted to methanofukrene isomers under thermal conditi~s.~,6b~t7
The ~than~ful~~ne
shifts of the carbons methanofullerene
dimctiy
and the fulleroid isomers are easily distinguish
attached
to the methano-bridge.
6b The sp3 hybridized
by the 1% NhSR carbons of the
isomers are observed between 70 and 90 ppm while the sp2 carbons attached to the methane-
bridge in the fulleroid isomers ~TGobserved between 130 and 150 ppm The observation of a signal at 83 ppm in the 1% NMR assigned~oo the ~-sp3 as a methanofullerene.
carbons definitively
This result is in accord with the experimentally
derivatives to exist as the methanofullerene isomer is not obmecl,
identifies the merhyl(me~ox~thano)fullemne
isomer rather than the full&d
observed preference for substituted isomer.wb
Although the fuller&d
it may have been formed during the course of the reaction since the reaction conditions
a~ sufficient K, induce its isomerization to the more stable methanofullerene
isomer.
9531
Successful compared
cyclopropanati~n
to the conditions
unencumbered it becomes
high electron-af%nity
for the reaction
of chromium
3-6 h)t4 and with more substituted,
of the cyclopmpanation
alkenes
co&ination
of &
reflux
carbenes
for 3 to 4 days. ,When with activated,
sterically
activated alkenes (100-l lO.C, 10-+I h),lS nature of the double bonds as welt as the
is believed
ruaction
to bc analogous
to that proposed
for
loss of a CO with free carbenes .*2.19 Thermally-induced This step is sensitive to the steric chromium ccmpkx.
and does not involve
of Qo generates an 7$-&t
nature of the alhenc sWatrate, but Q~J is an cxcelknt
org~ometallic
benzene
of C& which accounts for the modest yield in the C&u cyc~
The mechanism
coordination
chemistry, 20 and this electronic
cyclopropanation reaction. Formal [2+2] cycloaddition elimination
a vigorous
is only partially countered by the pyramidal&d
double bonds of m
and tkctronic
required
that C!eo is a sluggjsh substrate. The low reactivity of the unactivated tetrasubstitttted
apparent
subsequent
necessary
alkencs (WC,
electron-deficient
of Qo
%-acceptor, as is well-documented’by
effect is potentkly
its
crucial to the success of the
produces a metaUacyclobutane
from which reductive
yields the methanofirlkrene.
In conclusion, as a potentially
the cyclopropa~tion
of C!eu by a Fischer chromium
general route to mcthanofullerenes.
Overall, the oxygen
ca&ne
complex has been realii
stabilized
carbcne complexes
are
hkely to be of specific interest due to their ease of preparation and the pmence of the ether functionality which provides
a handle for further functionalixation
of the methanofulkrenes.
such as the more reactive molybdcnntn and non-hetematom readily with C&2’
stabii
are expected tc react
Studies on thcsc fronts are in progress.
i40
Figure. Fulkrene
Other Fischer carbene complexes
carbene complexes
138
region of the 13C Nh4R of 1,2-met.byl(methoxymethano)fullemne_CM
136
9532
Acknowledgement: research. References ::
Z:
2: 7. 8. 9. 10. 11. 12.
13. 14_ 15. 16.
17. 18. 19. 20. 21.
We thank the National
Science
Foundation
(CHE-9257081)
for support
of this
and Notes:
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(Received in USA 6 October 1994; accepted 3 November 1994)