Difference between revisions of "Synthesis of Lignin Monomers"

By:Alexandria N. Tibbs

Motivation

Introduction

Lignin is the second most abundant organic polymer. It is found in plants, majorly in trees. Its function is to serve in the assistance of water flow throughout the plant. It forms a barrier for the evaporation, trapping the water inside.

The structure of lignin is composed of the seemingly random combination of three monomers: p-coumaryl alcohol, coniferyl alcohol, and sinapyl alcohol.

Lignin Precursors

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These lignin monomers are derived from their acid precursors through the reduction of an aldehyde to the corresponding alcohol. While the acid precursors,p-courmaric acid (p-coumaryl alcohol), ferulic acid (coniferyl alcohol), and sinapic acid (sinapyl alcohol) may not be as abundant in nature, when it comes to the lab setting, these chemicals are easier to come by then their alcohol forms. The synthesis of theses alcohols can save a research space a great deal of money, if experiments require the alcohol forms of these monomers.

Materials

Diisobutylaluminum hydride solution (25 wt.% in toluene)

Product Number: 192724-100G

Quantity: 2

Price: $52.20

Toluene (Anhydrous, 99.8%)

Product Number: 244511-1L

Quantity: 1

Price: $60.50

Experimental

The esterfication of ferlic acid was the first step in the reduction of ferulic acid to coniferyl alcohol. First attempt was made using a 0.24M solution of ferulic acid in ethanol (250 mL ethanol, 12.1g ferulic acid). Along with 3 drops of concentrated HCl this was allowed to reflux for two days. The resulting solution was evaporated at low pressure, leaving a solid. This solid was then resolubilized in ethyl acetate (250 mL) and rinsed with sodium bicarbonate (2x100 mL) and brine (50 mL). The solution was dried using magnesium sulfate and evaporated at low pressure, resulting in an oil like solution. The final product was testing in the HPlc (Figure 1).

A second attempt at the esterfication of ferukic acid was carried out using the same method as above, but on a 1/5 scale. An HPLC was done of the intermediate that is present after 1 day of refluxing (Figure 1).

Results

Figure 1: HPLC Results after esterfication of Ferulic Acid

Figure 1 displays the results of HPLC testing that was run on 3 separate samples. The first is the ferulic acid standard. The second is a sample of the final product from the first attempt at the esterfication of ferulic acid. The third is a more dilute sample of the same sample from the second graph. All samples were run using the acquisition method: pCou_100417_SAZT.

Figure 2: Reaction of ferulic acid to ethyl ferulate

Figure 2 displays the chemical reaction of ferulic acid into ethyl ferulate. This displays the chemical process that occurs during the first steps of this reaction.

Figure 3: HPLC Results after second attempt at esterfication of Ferulic Acid

Figure 3 displays the results of HPLC testing that was run on 3 separate samples. The first graph represents the sample of the reflux intermediate from the second attempt at the esterfication process.The second is the ferulic acid standard. The third is the sample of the reflux intermediate from the second attempt at esterfication of ferulic acid after one and a half days of reflux. The fourth graph is the results from a sample of the final product, indicating the esterfication of ferulic acid to ethyl ferulate. The fifth graph is the product, coniferyl alcohol, after the DIABL-H steps of the reaction. All samples were run using the acquisition method: pCou_100417_SAZT.

Discussion

References

Lignin Biosynthesis and Structure

Oxidative Coupling during Lignin Polymerization is Determined by Unpaired Electron Delocalization within Parent Phenylpropanoid Radicals

[Overview from Lignin and Lignans: Advances in Chemistry]

Facile Large-Scale Synthesis of Coniferyl, Sinapyl, and p-Coumaryl Alcohol