Effect of Protein Intake on Post Prandial Hyperglycemia in Children and Adolescents With Type1 Diabetes Mellitus

In target glycemic control in children with type 1 diabetes (T1D) continues to be a challenge despite advances in methods of insulin delivery and medical knowledge in this area. One of the major aspects is controlling postprandial glycemia (PPG). The relationship between dietary intake of carbohydrates and PPG is well established, and the use of insulin coverage for carbohydrate intake is standard of care. Insulin dose for carbohydrate coverage increases with body weight and progression through puberty. Multiple researchers have attempted to study the effect of dietary intake of protein and fat on PPG as well, but this relationship is not well established in the pediatric age group and there are not clear guidelines for patients on when and how to give insulin for protein intake.

Meals with high protein content have been shown to cause higher glucose excursions in patients with T1D, and lower glycemic response in healthy individuals which suggests that physiologic response to protein intake involves higher insulin secretion. This has also been demonstrated by Sun et al, where they showed an increase in insulinemic index in healthy individuals when consuming chicken with rice compared to rice alone.

The effect of dietary protein in individuals with T1D has been studied in mixed meals several times. Smart et al demonstrated that the greatest glucose excursions after high protein low fat meal occurred most significantly form min 150 to 300 after the meal, when insulin is given to cover carbohydrates only. In 2013, Borie-Swinburne et al measured interstitial glucose levels by CGM in 28 c-peptide negative T1D patients, on two consecutive nights, with and without addition of 21.5 grams of protein to dinner (40 g vs 61.5 g). They concluded that no additional insulin is needed to cover for the added protein. Neu et al studied 15 adolescents with T1D on two consecutive nights. They used CGM monitoring for 12 hours, and they compared the area under the curve (AUC) between regular meals and fat/ protein rich meal. They found a significant difference and they recommended additional insulin for fat /protein rich meals.

Investigating the effect of protein-only intake is also an area of research focus. Paterson et al studied 27 patients with TID , aged 7-40 yrs, where they were given 6 test meals of varying amounts (0g, 12.5g, 25g, 50g, 75g and 100g) of pure protein without giving insulin. Postprandial glycemia was found to be significantly higher only for 75 and 100 grams of protein compared to the lower quantities. Glucose levels were slower to rise when compared to consumption of 20 grams of carbohydrates. Paterson et al also conducted another study with slightly different design: 27 participants with T1D [aged 10-40 years, HbA1c ≤ 64 mmol/mol (8%), BMI ≤ 91st percentile] received a 30-g carbohydrate (negligible fat) test drink with a variable amount of protein daily over 5 days in randomized order. Protein (whey isolate 0 g/kg carbohydrate, 0 g/kg lipid) was added in amounts of 0 (control), 12.5, 25, 50 and 75 g. A standardized dose of insulin was given for the carbohydrate. PPG was assessed by 5 hours of continuous glucose monitoring. Increasing protein quantity in a low-fat meal containing consistent amounts of carbohydrate decreases glucose excursions in the early (0-60-min) postprandial period and then increases in the later postprandial period in a dose-dependent manner. In summary, Paterson et al concluded that there was a threshold for dietary protein intake (75 grams), and only protein intake above this threshold regardless of body weight would result in post prandial hyperglycemia. However, these studies included a wide range of ages and did not adjust for body weight in their analysis.

B. Innovation The purpose of this study is to explore the role of weight in the relationship between protein intake and post prandial glucose (PPG) levels. The study design (36 children each receiving 6 increasing nominal doses of protein) allows for the relationship to be studied both across patients of varying weights within each nominal dose, and across patients (whose weights remain the same) across the increasing doses.

Our aims:

Aim 1: To describe the relationship of weight (in kg), and mg of protein per kg body weight, to PPG, graphically and statistically, at each nominal dose. The heaviest children will receive the lowest mg/kg amount of protein at each nominal dose, so these relationships with PPG will be inverse. Additionally, children with different weights and receiving different nominal doses, may be receiving the same mg/kg protein. Observing all nominal doses together will allow us to determine whether the relationship, if any, is linear, demonstrates a threshold, or exhibits a doseresponse curve, as examples.

Aim 2: To describe graphically and statistically the relationship of dose of protein to PPG by patient across increasing doses. Since the weight remains constant (or approximately constant) within a patient, adjustment by weight would yield the same results. The expectation is that these results will confirm those from Aim 1.

Aim 3: To construct a multivariate mixed model where any observed relationships can be controlled for other demographic and clinical characteristics possibly associated with blood glucose levels. The type of model will depend on the results of Aims 1 and 2.