The above reaction shows an epimeric steroid alcohol being converted by a catalyst of ruthenium and aluminum oxide to a racemic mixture of 17-estradiol 3-methyl ether and a ketone. The racemic mixture is formed by converting the beta version of the ether, where the hydroxyl group is on the top of the ring, to the alpha version of the ether, where the hydroxyl group is underneath the ring. The reaction is stopped when the amount of alpha ether is roughly equivalent to the amount of beta ether. In the notation used, the wavy line between the hydroxyl group and the ether shows that the hydroxyl group can be in either the front or the back of the molecule.
However, a ketone can be produced instead of the alpha ether when the alcohol is oxidized. Because the purpose of the reaction is to racemize the ether, this ketone is an unwanted side product. To prevent oxidation, toluene at 100 C is used as a solvent. The chemical properties of toluene slow the formation of the ketone so that at temperatures around 100 C, the yield of the racemic mixture is about 54%. Any ketone that does form can be separated from the ether by flash chromatography. This reaction is a good way to racemize the ether efficiently and inexpensively; it was traditionally synthesized at a much higher cost.
This is en example of what we learned in class, the Markovnikov hydration of n-propyne (a terminal Alkyne) that produces a Ketone. Using ACS publications, i found an article that describes an ideal anti-Markovnikov hydration of the same compound, to produce an Aldehyde instead.
To induce this reaction, the catalyst cyclopentadienylruthenium is used in a 2-Propanol solvent at 100 deg C, with yields over 99% for this reaction, other Alkynes bearing over 90% for the most part.
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This is an example of the reaction of a ketone with a Grignard reagent, which gives a tertiary alcohol. The paper presents a study of several different idol-3-ones reacting with Grignard reagents. Idol-3-ones are potentially useful intermediates in the synthesis of alkaloids and pharmaceutical agents.
Going one step further: due to the lack of stability in the tertiary alcohol, a rearrangement is observed on the alcohol molecule, creating a gain in resonance stabilization in the final molecule. The study examined a variety of conditions under which the rearrangement occurred, in order to recognize the most efficient one. It was determined that the rearrangement took place with great facility under acidic or basic conditions or was thermally induced.
