Intestinal fat absorption shifting by polyglucosamine biopolymer: control of lipids and reduction of progression of early subclinical atherosclerosis.

BACKGROUND: Atherosclerosis progression is possible in subjects with limited alteration of body weight, lipid profile, and oxidative stress. The ultrasound carotid thickness (IMT) and arterial wall modification (granulation and bubbles) are evident signs of the disease. Intestinal fats absorption shifting (IFAS) is expected to prevent or reduce the arterial damage. The aim of the registry was to evaluate the effects of a mild diet in association with lifestyle modifications (standard management [SM]) and SM+ a polyglucosamine biopolymer (BP) shifting the intestinal absorption of dietary fats.

METHODS: The present is a two-year registry comparing two groups of otherwise healthy subjects, respectively 150 (SM) and 144 (SM+BP). BP was administered at the dosage of 3g/day. IMT and relative arterial damages were measured together with lipid profile, oxidative stress, anthropometric and vital measures.

RESULTS: The two groups at the baseline were comparable for all variables: 8 cases of drop out were found limited to SM. Compliance with BP was optimal (>97%) and no side effect were observed. IMT showed a significant decrease in thickness (P<0.05) using BP+SM, while increased in SM group. Intimal granulations and lipid wall bubbles were also significantly decreased with BP in comparison to SM only (P<0.05). BMI significantly decreased with BP (P<0.05) as well as BW, fat mass, lipid profile and oxidative stress in comparison to SM only. A positive variation in blood pressure and heart rate (P<0.05) was also observed.

CONCLUSIONS: BP allows IFAS to improve early subclinical arterial lesions that tend to progress to plaques and clinical events. The long-term and safe treatment of BP is effective on IMT, lipids, BW, and early lesions of the arterial wall structure in subjects with subclinical conditions. BP also reduces oxidative stress which contributes to lipid oxidation and deposition into the arterial wall layer in areas of high dynamic stress (arterial bifurcations).