Stereoselective synthesis, CLW

Revision of previously encountered selective reactions

As an example of chemoselectivity (selectivity between different functional groups), consider reduction of carbonyl compounds with metal hydrides
NaBH₄ is very mild and reduces ketones in the presence of esters
LiAlH₄ reduces both ketones and esters
In a keto-ester: (i) protect the ketone with ethylene glycol and H⁺, (ii) reduce the ester with LiAlH₄, then (iii) deprotect with H⁺/H₂O
It's preferable to avoid protecting groups wherever possible

As an example of regioselectivity (selectivity between parts of the same functional group), consider addition of carbon nucleophiles to enones
Hard nucleophiles like MeLi undergo direct addition (1,2-addition) to the carbonyl carbon, forming an alcohol
Soft nucleophiles like Me₂CuLi undergo conjugate addition (1,4-addition, Michael reaction) to the β carbon, forming ketone

As an example of stereoselectivity (control over stereochemistry), consider epoxidation of a chiral cyclic allylic alcohol with mCPBA
Option 1: Don't protect the OH group
- the OH group forms a hydrogen bond to mCPBA – chelation control
- mCPBA delivers an oxygen atom to the top (hydroxy) face of the unprotected allylic alcohol
Option 2: Protect the OH group with Ac₂O/py to get a chiral allylic acetate
- mCPBA delivers an oxygen atom to the bottom (unblocked) face of the allylic acetate

Diisobutylaluminium hydride (DIBALH) is less flammable and easier to use than LiAlH₄
It selectively reduces esters to aldehydes, if the reaction is conducted at −70 °C
An ester oxygen coordinates to Al, then hydride migrates from Al to C
The tetrahedral intermediate is stable at low temperature, and can be worked up with H⁺/H₂O to the aldehyde
Yields well over 90% when done properly

Stereoselective reduction of cyclohexanones with the bulky reagent L-selectride, Li[HB(sBu)₃]
Small nucleophiles like LiAlH₄ prefer axial attack (OH group ends up equatorial rather than axial – the thermodynamic product)
Bulky nucleophiles likes Li[HB(sBu)₃] prefer equatorial attack to avoid steric clash with 1,3-hydrogens (OH group ends up axial – the kinetic product)