Hippadine is naturally produced in plants and shows signs that it is good for the heart.1
Figure 1, Synthesis of Hippadine
There were
a total number of 4 steps shown on the Chemistry by Design site, but there were
some left out. In each step shown above the
reagents used are readily available. (The availability of each was determined
from the Sigma Aldrich website).
In step 1,
the reagent is vinyl magnesium bromide and tetrahydrosfuran is used as the
solvent. Step 2 utilizes
5-bromo-6-bromomethyl-1,3-benzodioxole with potassium hydroxide (KOH) and
dimethyl sulfoxide (DMSO). The third
step n-Butyllithium (n-BuLi) is used in THF and in the final step barium manganate
is the reagent used in dichloromethane (DCM).
Of the 4
steps, three have been discussed in class.
The first step uses a Gringard reagent, which follows the basic
structure of R-Mg-X. In this case the R
group is CH3 and the X group is Br. The third step is one in which an organolithium
reagent is used. Since Li is an electropositive
metal, it contains a very polar carbon-metal bond causing it to be very
reactive.2 An Ullman Reaction was utlizied in this step as
well. Such reactions were not discussed in
class, but the Ullmann-type Reactions include copper-catalyzed nucleophilic
aromatic substitution between various nucleophiles with aryl halides.3
The final step is an oxidation in which the oxygen is double bonded to the
carbon using the reagent BaMnO4.
Below is a different mechanism of
the synthesis of Hippadine with a different starting material.
Figure 2, Synthesis of Hippadine4
Resources
1Purgett,
Thomas. https://honors.tcu.edu/QAwithStudentsCompletingDepartmentalHonors.asp
2Smith,
Janice. Organometallic Reagents. Organic Chemistry, 3rd Edition.
McGraw Hill. New York. Print. Pp 739
3M.
Cortes-Salva, C. Garvin, J. C. Antilla, J. Org. Chem., 2011, 76, 1456-1459
4Boger, D. L.; Wolkenberg, S. E. J. Org. Chem.
2000, 65, 9120-9124
