Pyrrole, osmium complex

The /3-electrophilic additions of pentaamineosmium(ll) complexes bearing various 4,5-tf -coordinated pyrroles to carbonyl compounds have been reported by Harman and co-workers (Scheme 78). 1 1-Methylpyrrole complex, when reacted with benzaldehyde or its dimethylacetal in the presence of /-butyldimethylsilyl triflate (TBSOTf), afforded the corresponding aldol adduct 177 as a 1 1 ratio of diastereoisomers. Pyrrole, 1-methylpyrrole, or 2,5-dimethylpyr-role osmium complexes reacted with an excess of acetone in the presence of TBSOTf to give the O-silylated 377-pyrrolium aldol adducts 178, which may serve as intermediates for various other reactions. 

Well-characterized 2-(chloromercurio) derivatives of 1-acetyl- and l-(phenylsulfonyl)pyrrole were prepared by reaction of HgCl2. These can be converted to />/s-(pyrrol-2-yl (mercury compounds or into ruthenium and osmium complexes by transmetallation. In all of these complexes there is coordination between the acetyl or sulfonyl oxygen and the metal, but the chelation is much tighter in the Ru and Os complexes <95JOM(491 )219> To date, the reactivity of these compounds has not been explored. 

A completely different device to encourage pyrroles to react as dienes is their conversion into osmium complexes in this way even traditional dienophiles will react under mild conditions as shown below adducts can be subsequently obtained by oxidative destruction of the metal complex. 

Harman and coworkers have explored the reactivity of -osmium complexes of pyrroles. These complexes can react as nonaromatic species in which the Os has localized two of the Ji-electrons. For example, the complex of 1-methylpyrrole gives a conjugate addition product with methyl vinyl ketone in the presence of TBDMS triflate <93JOC4788>. Decomplexation by reaction with a base gives a 3-substituted pyrrole (Scheme 131). 

Glucose oxidase polymer of pyrrole fiinctionalized with osmium complex entrapment amperometric (based on redox of Os complex) 78... 

Organometallic chemistry of pyrrole is characterized by a delicate balance of the ti N)- and -coordination modes. Azacymantrene is an illustration of the considerable nucleophilicity of the heteroatom. However, azaferrocene can be alkylated at C2 and C3 sites. Ruthenium and osmium, rhodium, and iridium chemistry revealed the bridging function of pyrroles, including zwitterionic and pyrrolyne complex formation. The ti (CC) coordination of osmium(2- -) allows versatile derivatizations of the heteroring. 

Furthermore, the utilization of preformed films of polypyrrole functionalized by suitable monomeric ruthenium complexes allows the circumvention of problems due to the moderate stability of these complexes to aerial oxidation when free in solution. A similar CO/HCOO-selectivity with regards to the substitution of the V-pyrrole-bpy ligand by an electron-with-drawing group is retained in those composite materials.98 The related osmium-based redox-active polymer [Os°(bpy)(CO)2] was prepared, and is also an excellent electrocatalyst for the reduction of C02 in aqueous media.99 However, the selectivity toward CO vs. HCOO- production is lower. 

The preceding sections describe regioselective electrophilic addition of pyrrole complexes at the 3-position with various electrophiles to give ( -substituted lZ/-pyrrole or 3//-pyrrolium isomers. The latter compounds, in contrast to their noncomplexed counterparts, are only moderately acidic (pKa 6) and therefore resist rearomatization and multiple alkylations. For example, when uncomplexed 2,5-dimethylpyrrole is treated with 1 equiv of methyl acrylate and TBSOTf, a statistical 1 2 1 ratio of starting material, monoalkylated 105 (vide infra), and 3,4-bis-alkylated product is found.12 Treatment of 1-methylpyrrole under the same conditions results in at least four alkylated products along with starting material. In contrast, coordination by osmium results in smooth... 

In addition to the high regiochemistry observed, the bulky osmium pentaammine metal center also effectively blocks one face of the pyrrole ring from attack. This directs each transformation carried out on the complex to occur on the same face of the pyrrole ring. For example, in the synthesis of 3-pyrroline complex 74, both protonation and hydride addition occur from the same face of the pyrrole ring, producing 74 exclusively as the c/s-isomer. This feature is also illustrated in the synthesis of pyrrolizinone 109 vide infra), where a stereoselective hydride reduction allows the preparation of 109 as only one diastereomer. 

In summary, the metal can be readily removed from both 1//-pyrrole and 3-pyrroline (including azanorbomene) complexes to give a wide variety of highly functionalized molecules not readily obtained from the aromatic precursors without the use of osmium. The inherent instability of 2-pyrrolines prevents clean decomplexation unless quatemization or acylation of the nitrogen is carried out prior to oxidation of the metal. 

As noted in Chapters 2 and 11, a series of -q -arene complexes of osmium have been prepared, and the reactivity of these species has been studied extensively by Harman. The reactions of iq -arene complexes of Os(II) illustrate how strong backbonding can cause the uncoordinated portion of an aromatic system to be more susceptible to electrophilic attack than the corresponding free arene. ° Osmium(II) pentamine complexes of phenols, anilines, acetanilides, and anisoles react with electrophiles at the uncoordinated portion of the ring. For example, the simple phenol complex in Equation 12.78 reacts with Michael acceptors at the 4-position of the coordinated phenol in the presence of a mild tertiary amine base. This reactivity and selectivity for reaction at the 4-position is greater than the reactivity of free phenol. The reactions of electrophiles with aniline derivatives occur in a similar fashion and lead to products from alkylation of the aromatic ring predominantaly at the 4-position (Equation 12.79). Related reactions occur with complexes of electron-rich five-membered pyrrole and furan heterocycles. Examples of electrophilic attack on -q -pyrrole complexes of Os(II) are shown in Equation 12.80. ... 

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