Maillard reaction


The Maillard reaction is a chemical reaction between amino acids and reducing sugars that gives browned food its distinctive flavor. Seared steaks, fried dumplings, cookies and other kinds of biscuits, breads, toasted marshmallows, and many other foods undergo this reaction. It is named after French chemist Louis-Camille Maillard, who first described it in 1912 while attempting to reproduce biological protein synthesis.
The reaction is a form of non-enzymatic browning which typically proceeds rapidly from around. Many recipes call for an oven temperature high enough to ensure that a Maillard reaction occurs. At higher temperatures, caramelization and subsequently pyrolysis become more pronounced.
The reactive carbonyl group of the sugar reacts with the nucleophilic amino group of the amino acid, and forms a complex mixture of poorly characterized molecules responsible for a range of aromas and flavors. This process is accelerated in an alkaline environment, as the amino groups are deprotonated, and hence have an increased nucleophilicity. This reaction is the basis for many of the flavoring industry's recipes. At high temperatures, a probable carcinogen called acrylamide can form. This can be discouraged by heating at a lower temperature, adding asparaginase, or injecting carbon dioxide.
In the cooking process, Maillard reactions can produce hundreds of different flavor compounds depending on the chemical constituents in the food, the temperature, the cooking time, and the presence of air. These compounds, in turn, often break down to form yet more new flavor compounds. Flavor scientists have used the Maillard reaction over the years to make artificial flavors.

History

In 1912, Maillard published a paper describing the reaction between amino acids and sugars at elevated temperatures. In 1953, chemist John E. Hodge, with the U.S. Department of Agriculture, established a mechanism for the Maillard reaction.

Foods and products with Maillard reactions

The Maillard reaction is responsible for many colors and flavors in foods, such as the browning of various meats when seared or grilled, the browning and umami taste in fried onions, and coffee roasting. It contributes to the darkened crust of baked goods, the golden-brown color of French fries and other crisps, of malted barley as found in malt whiskey and beer, and the color and taste of dried and condensed milk, dulce de leche, the Sri Lankan confection milk toffee, black garlic, chocolate, and roasted peanuts.
6-Acetyl-2,3,4,5-tetrahydropyridine is responsible for the biscuit or cracker-like flavor present in baked goods such as bread, popcorn, and tortilla products. The structurally related compound 2-acetyl-1-pyrroline has a similar smell, and also occurs naturally without heating and gives varieties of cooked rice and the herb pandan their typical smells. Both compounds have odor thresholds below 0.06 ng/l.
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The browning reactions that occur when meat is roasted or seared are complex, and occur mostly by Maillard browning with contributions from other chemical reactions, including the breakdown of the tetrapyrrole rings of the muscle protein myoglobin.
Caramelization is an entirely different process from Maillard browning, though the results of the two processes are sometimes similar to the naked eye. Caramelization may sometimes cause browning in the same foods in which the Maillard reaction occurs, but the two processes are distinct. They are both promoted by heating, but the Maillard reaction involves amino acids, as discussed above, whereas caramelization is simply the pyrolysis of certain sugars.
Maillard reactions also occur in dried fruit.
In making silage, excess heat causes the Maillard reaction to occur, which reduces the amount of energy and protein available to the animals that feed on it.

Chemical mechanism

  1. The carbonyl group of the sugar reacts with the amino group of the amino acid, producing N-substituted glycosylamine and water
  2. The unstable glycosylamine undergoes Amadori rearrangement, forming ketosamines
  3. Several ways are known for the ketosamines to react further:
  4. * Produce two water molecules and reductones
  5. * Diacetyl, pyruvaldehyde, and other short-chain hydrolytic fission products can be formed.
  6. * Produce brown nitrogenous polymers and melanoidins
The open-chain Amadori products undergo further dehydration and deamination to produce dicarbonyls.
This is a crucial intermediate.
from open-chain Amadori compound
Dicarbonyls react with amines to produce Strecker aldehydes through Strecker degradation.
Acrylamide, a possible human carcinogen, can be generated as a byproduct of Maillard reaction between reducing sugars and amino acids, especially asparagine, both of which are present in most food products.