Changing the form of the functional group to the substituent you want is important in organic chemistry. When you perform a synthetic reaction, you have to synthesize a compound that has the functional group you want.

One of those synthetic reactions is carbonyl reduction. Among the reduction reactions, the reduction of carbonyl compounds is an important synthetic reaction. There are many functional groups with C=O structure, and we have to learn which functional groups can be used to reduce carbonyl compounds.

Regioselectivity is also important. It is common for a single compound to have several functional groups and only certain functional groups need to be reduced.

Depending on the reagent to be used, the reduction of a carbonyl group is different. So we will explain how to think about carbonyl reduction.

Carbonyl Reduction by Hydride Reducing Agents

There are many compounds with a C=O structure; molecules with a C=O functional group are called carbonyl compounds. Examples of carbonyl compounds include the following.

  • Aldehyde (formyl group)
  • Ketone (carbonyl group)
  • Ester
  • Amide
  • Carboxylic acid

Hydride reducing agents are frequently used to reduce these compounds.

Reducing agents that give hydride (H) are called hydride reducing agents. By mixing the carbonyl compound with a hydride reducing agent, C=O is reduced. As a result, the form of the functional group is changed.

Reduction of Different Carbonyl Compounds in NaBH4 and LiAlH4

There are several types of hydride reducing agents. Specifically, the following types of reducing agents are utilized in carbonyl reduction.

  • Sodium borohydride (NaBH4)
  • Lithium borohydride (LiBH4)
  • Lithium aluminium hydride (LiAlH4)
  • Borane (BH3)

These reducing agents are used. Sodium borohydride (NaBH4) and lithium aluminium hydride (LiAlH4) are particularly important in hydride reduction.

Lithium aluminium hydride (LiAlH4) is highly reactive and reduces most carbonyl compounds. It is also highly reactive and will ignite when in contact with water. Sodium borohydride (NaBH4), on the other hand, allows the synthesis to proceed under moderate conditions.

Sodium borohydride (NaBH4) and lithium aluminium hydride (LiAlH4) are different in terms of the functional groups that can be reduced. In the case of sodium borohydride, the reduction of aldehydes (formyl groups) and ketones (carbonyl groups) is possible.

On the other hand, lithium aluminium hydride can reduce most carbonyl compounds. Therefore, it is necessary to use a different hydride reducing agent depending on the compound to be reduced.

-More Detailed Description of Functional Group Selectivity and Differences between Hydride Reducing Agents

It is important to note that different hydride reducing agents have different functional groups that can be reduced. By utilizing this difference, only certain functional groups can be reduced in a regioselective manner.

For example, suppose we have a compound with ketones and carboxylic acids in the molecule. When sodium borohydride (NaBH4) is added to this compound, only the ketones are reduced. This is because sodium borohydride does not reduce carboxylic acids.

In this way, the molecules can be reduced in a regioselective manner.

Note that we have just checked only the reduction of sodium borohydride and lithium aluminium hydride. However, there are other important hydride reducing agents as well. The functional group selectivity of hydride reducing agents is shown below.

By using the different functional groups that can be reduced, you can reduce only the desired part of the molecule and get the compound you want.

Hydride Migration Is Important in the Reaction Mechanism

When using hydride transfers, hydride transfer reaction is an important reaction mechanism. The H is the hydride and the carbonyl compound is reduced by the nucleophilic attack of the hydride. The reagent that causes hydride migration is a hydride reducing agent.

Then, how does hydride transfer reaction occur? As an example, the reaction mechanism of sodium borohydride (NaBH4) reacting with a carbonyl compound in the ethanol solvent is described below.

When a hydride reducing agent is added, the H nucleophilic attack on the carbonyl carbon by hydride migration. At the same time, the electrons forming the C=O double bond are transferred to the oxygen atom. The negatively charged oxygen atom then takes away the hydrogen atom of the ethanol. As a result, the compound is reduced to alcohol (hydroxy group: -OH).

The ethanol loses the hydrogen atom and thus ethoxide is formed. The ethoxide then reacts with sodium borohydride, which released the hydride, to form sodium ethoxyborohydride.

Like sodium borohydride (NaBH4), sodium ethoxyborohydride has the ability to reduce carbonyl compounds. Since sodium ethoxyborohydride has three hydrogen atoms bonded to it, it can reduce carbonyl compounds three more times.

Various Reduction Methods for Carbonyl Compounds

So how can we reduce carbonyl compounds? As mentioned above, there are many types of carbonyl compounds. For each functional group, you have to choose the best hydride reducing agent.

In the use of hydride reducing agents, it is necessary to use different reagents depending on the functional group to be reacted with. Specifically, consider the following

  • Reduction of ketone or aldehyde to alcohol: use NaBH4
  • Reduction of ester to alcohol: use LiBH4
  • Reduction of amides to amines: use LiAlH4
  • Reduction of carboxylic acid to alcohol: use BH3
  • Reduction of Esters to Aldehyde: use DIBAL-H
  • Reduction of amides to aldehydes: use LiAlH4 (low temperature: 0°C)

In the actual organic synthesis, it is necessary to understand the reduction method for each functional group. Therefore, we will explain the reduction method for each functional group.

Converting Ketones and Aldehydes to Alcohol

In the case of compounds with ketones (carbonyl groups) and aldehydes (formyl groups) in the molecule, they can be converted to alcohols with the use of hydride reducing agents.

It is known that by oxidizing alcohol, ketones or aldehydes can be synthesized. In other words, by using a reducing agent, the reverse can be done, converting ketones and aldehydes to alcohols.

The most used reagent in the reduction of ketones and aldehydes is sodium borohydride (NaBH4). Lithium aluminium hydride (LiAlH4) can also be used for the reduction, but as mentioned above, LiAH4 ignites when reacting with water and other substances. In addition, LiAH4 produces byproducts when it reacts with other functional groups.

Therefore, NaBH4 is used for selective reduction of ketones and aldehydes. The reaction mechanism is as follows.

We have just described the reaction mechanism using hydride reducing agent. The exact same reaction mechanism is used for hydride reduction.

Use Lithium Borohydride in the Reduction of Alcohol from Ester

On the other hand, how do we reduce an ester to alcohol? For ketones and aldehydes, sodium borohydride (NaBH4) quickly reduces the compound. However, the reaction with esters is extremely slow.

Therefore, lithium borohydride (LiBH4) is used in the reduction reaction of esters. Due to its strong reduction action, even the ester can be easily reduced to alcohol.

When the ester is reduced by the hydride reducing agent, the reaction mechanism is a bit more complex than the previous one. It is as follows.

After the hydride migration causes a nucleophilic attack, the ester is left. The result is the formation of aldehydes.

However, if a hydride reducing agent is present in the solution, the aldehyde will be reduced to an alcohol. Therefore, the ester is finally converted to alcohol by LiBH4. By reducing the structure of -COOR, it can be converted to -CH2OH.

The ester can also be reduced by lithium aluminium hydride (LiAlH4), but as mentioned above, it reacts with water and explodes, causing a fire hazard. On the other hand, lithium borohydride (LiBH4) is less likely to cause a fire accident than LiAlH4, since the reaction proceeds under moderate conditions.

The Method of Amine Synthesis from Amides Is based on Lithium Aluminium Hydride

As a carbonyl compound, a molecule with a stable structure is an amide. The stable structure means that they are difficult to react with. Therefore, amide reduction utilizes lithium aluminium hydride (LiAlH4), a powerful hydride reducing agent.

Amides can also be reduced to synthesize amines. In the reduction of amides, the respective structures can be converted as follows.

  • -CO-NH2 → -CH2-NH2
  • -CO-NRH → -CH2-NRH
  • -CO-NR2 → -CH2-NR2

The reaction mechanism is similar to that of an ester. However, unlike the ester, iminium ion is generated as an intermediate. We described above that in ester, hydride reducing agent generates aldehyde in the middle of the reaction. On the other hand, in the case of amides, the intermediate is an iminium ion.

The reaction mechanism of hydride reduction to amides is as follows.

Nucleophilic attack on the iminium ion causes hydride migration to occur again. The result is an amine.

Carboxylic Acid to Alcohol with Borane.

On the other hand, how are carboxylic acids reduced? Lithium aluminium hydride (LiAlH4) is a highly reactive hydride reducing agent. However, the reaction hardly proceeds when LiAlH4 is added to the carboxylic acid. The reaction of the carboxylic acid finally proceeds when the carboxylic acid is reacted under a long time and high temperature conditions.

Why does LiAlH4 react poorly with a carboxylic acid? LiAlH4 is also a base, and H+ is pulled out of the carboxylic acid by the acid-base reaction. When the reaction by hydride reduction proceeds in this state, dianions are formed as intermediates.

In dianions, two oxygen atoms are coordinated with Al+. This makes the reduction reaction less likely to occur. For these reasons, other reagents are usually used in the reduction of carboxylic acids. Specifically, borane (BH3) is used as a reducing agent.

Borane has an empty p-orbital and is known to act as a Lewis acid. Therefore, unshared electron pair on the oxygen atom of the carboxylic acid attacks the borane and bonds with the boron atom. Subsequently, the oxygen atom bonded to the boron atom is left.

This is how the reduction reaction proceeds. The reaction mechanism is as follows.

Since borane, which is a Lewis acid, forms a trimer, it is actually a more complex reaction mechanism. However, for the sake of clarity, we have described the reaction mechanism in a simple way, assuming that a single molecule reacts with each other.

Borane can quickly reduce amides and carboxylic acids. On the other hand, it hardly reacts with aldehydes, ketones and esters. Therefore, it has excellent functional group selectivity.

Reduction of Ester to Aldehyde by DIBAL-H

So far, we have discussed the reaction of synthesizing alcohols by reduction. To review, the reduction of esters produces aldehydes as intermediates. Is it possible to obtain an aldehyde compound by stopping the reaction process with an aldehyde?

With the hydride reducing agents that we have been explaining, it is impossible to stop the reaction with aldehydes. The general method is to synthesize alcohol and then obtain the aldehyde by an oxidation reaction. However, with some reagents, aldehydes can be synthesized directly from esters.

One such reagent is diisobutylaluminium hydride (DIBAL-H). By reacting with the ester at -70°C, DIBAL-H becomes a stable tetrahedral intermediate.

The compound is then decomposed by the addition of water to give the aldehyde. Note that the reaction mechanism of DIBAL-H is similar to that of borane.

Amides Are Reacted with LiAlH4 under Low Temperature Conditions to Obtain Aldehyde

Other methods exist for synthesizing aldehydes by hydride reduction. One of them is the reaction of an amide with lithium aluminium hydride (LiAlH4) at low temperature (0°C).

As explained in the reduction of amide by LiAlH4, iminium ion is formed as an intermediate. It is important to note that when an amide reacts with LiAlH4 at low temperature, the reaction does not proceed to the amine, but stops when the iminium ion is formed.

If water is added to an iminium ion, the compound will be hydrolyzed. The hydrolysis of iminium ion has the following reaction mechanism.

After reacting at 0°C, the iminium ion is converted to an aldehyde by the same reaction mechanism as the hydrolysis of imine.

Differences in Hydride Reducing Agents, Strength and Functional Selectivity

How to reduce a compound is one of the most important reactions in organic chemistry. When reducing a compound, carbonyl compounds are important. There are many types of carbonyl compounds, such as ketones, aldehydes and esters, and we must use a hydride reducing agent for each functional group.

Most of the hydride reducing agents contain metals and their reducing power is different. In addition, there is a difference in the type of functional group that can be reduced and the speed of the reduction.

By selecting the reducing agent, it is possible to selectively reduce only the specific functional group. Typical hydride reducing agents are listed along with their reaction mechanisms, so you should try to understand what kind of reduction agent to use.

In carbonyl reduction, there are many types of hydride reducing agents that are options. The reaction mechanism is also different. This can make it more complicated, but it is an important organic reaction, so it is essential to learn about it beforehand.