Protein Digestion & Absorption Clinical Trial
Official title:
The Impact of Milk Protein Glycation on Protein Digestion and Absorption in Healthy Young Men
Rationale: Protein intake is an essential stimulus for muscle protein anabolism. The muscle protein synthetic response to protein ingestion is mainly determined by the post-prandial plasma amino acid response. Milk protein often undergoes glycation during commonly applied milk processing procedures (Maillard reaction). We have previously shown that glycated protein results in lower postprandial amino acid levels. The level of protein glycation in processed dairy products might therefore be an important modulator of the overall protein quality of a product, and its ability to stimulate protein metabolism. However, it has not yet been investigated if the glycation level of dietary protein modulates its appearance in plasma as amino acids. Objective: To compare the appearance of dietary protein-derived amino acids in plasma after ingestion of a milk protein powder with different levels of protein glycation in healthy young men. Study design: Double blinded, randomized cross-over study. Study population: 15 healthy young males, aged 18-35 years. Intervention (if applicable): All subjects will perform two experiments in a double-blinded, randomized order: ingest 40 g of milk protein with 5% glycation level in 600 mL water, or 40 g of milk protein with 50% glycation level in 600 mL water. After ingestion, blood samples will be taken at regular intervals during a 6 hour period. Main study parameters/endpoints: The primary endpoint will be the appearance of milk protein-derived amino acids in plasma over the full assessment period (6 h), as determined using stable isotope tracer methodology.
Proteins are mainly required as building blocks for muscle maintenance and muscle growth. To supply these building blocks for growth and development, proteins need to be well digested, and absorbed in the circulation. Processing of milk to produce dairy products, such as milk protein powders, may affect protein quality. Heat processes can impact native protein structure, for example by inducing protein denaturation and aggregation. In addition, reducing sugars such as lactose can react with the amino group of amino acids, known as the Maillard reaction or protein glycation. Glycation levels in milk protein powders can range from 5-50%, depending on factors such as water content and storage temperature. Several in vitro and animal studies have shown that protein glycation decreases protein digestibility. In addition, we have recently demonstrated that protein glycation reduces post-prandial amino acid availability in humans. This reduced postprandial amino acid availability could mostly be attributed to a reduction in postprandial availability of the essential amino acid lysine. The lower post-prandial availability of amino acids following ingestion of protein with a high glycation level suggests an impaired digestion and absorption of glycated dietary protein. Therefore, to test whether ingestion of a high glycated milk protein results in a lower appearance of dietary protein-derived amino acids, a human trial has been designed. Subjects will consume a low or high glycated milk protein drink, where after several blood samples will be taken to assess the appearance of dietary protein-derived amino acids over time by using a continuous amino acid tracer infusion. The low and high glycated protein drinks reflect the lower and upper range of protein glycation reported in dairy protein products. We hypothesize that protein glycation attenuates the appearance of dietary protein-derived amino acids in plasma. ;