A novel dietary multifunctional ingredient reduces body weight and improves leptin sensitivity in cafeteria diet-fed rats

Clock system disruption in male Fischer 344 rats fed cafeteria diet and administered sweet treats at different times: The zeitgeber role of grape seed flavanols

Current lifestyles include calorie-dense diets and late-night food intake, which can lead to circadian misalignment. Our group recently demonstrated that sweet treats before bedtime alter the clock system in healthy rats, increasing metabolic risk factors. Therefore, we aimed to assess the impact of the sweet treat consumption time on the clock system in rats fed a cafeteria diet (CAF). Moreover, since flavanols have demonstrated beneficial effects in metabolic disorders and clock gene modulation, we also investigated whether these phenolic compounds can restore the circadian disruption caused by these altered dietary patterns. For this, 64 Fisher rats were fed CAF for 9 weeks. In the last 4 weeks, animals were daily administered a low dose of sugar (160 mg/kg) as a sweet treat at 8 a.m. (ZT0) or 8 p.m. (ZT12). Two other groups received 25 mg/kg of grape seed flavanols in addition to sweet treats. Finally, the animals were sacrificed at different time points (9 a.m., 3 p.m., 9 p.m., and 3 a.m.). The results showed that metabolic and circadian disturbances by CAF may be influenced by the time of sugar administration, slightly reinforcing the alterations in diurnal rhythmicity of serum biochemical parameters, hormones, and hypothalamic genes with bedtime snacking. Flavanols improved metabolic health and restored the oscillation of biochemical parameters, hormones, and clock and appetite-signaling genes, showing greater effects at ZT12. These results highlight the importance of meal timing in influencing physiological and metabolic outcomes, even under calorie-dense diets. Moreover, they also suggest the zeitgeber role of flavanols, modulating the clock system and contributing to an improved metabolic profile under different feeding pattern conditions.

Leptin pathway is a crucial target for anthocyanins to protect against metabolic syndrome

The high prevalence of metabolic syndrome is threatening the health of populations all over the world. Contemporary work demonstrates that high leptin concentration is directly related to the development of metabolic syndrome such as obesity, fatty liver diseases, type 2 diabetes mellitus and cardiovascular diseases. Anthocyanins are a widespread group of dietary polyphenols, which can ameliorate chronic diseases related to metabolic syndrome. In addition, anthocyanins can regulate the leptin pathway in chronic metabolic diseases, however the potential mechanism between anthocyanin and leptin is complex and elusive. In this review paper, we have evaluated the bioactivity of anthocyanins on the mediation of leptin level and the upstream and downstream pathways in chronic metabolic diseases. Anthocyanins could regulate the hypertrophy of adipose tissue, and the expression of leptin level via mediating TNF-α, C/EBP, PPAR, CREB and SREBP-1. Anthocyanins promoted the leptin sensitivity by increasing the level of leptin receptor, phosphorylation of JAK2/STAT3, PI3K/AKT, and additionally ameliorated metabolic disorder related outcome, including oxidative stress, inflammation, lipid accumulation, insulin resistance and the balance of gut microbiota. However, direct evidence of anthocyanins treatment on leptin signal transduction is still limited which calls for future molecular binding and gene regulation test.

Valorization of Chicken Slaughterhouse Byproducts to Obtain Antihypertensive Peptides

Hypertension (HTN) is the leading cause of premature deaths worldwide and the main preventable risk factor for cardiovascular diseases. Therefore, there is a current need for new therapeutics to manage this condition. In this regard, protein hydrolysates containing antihypertensive bioactive peptides are of increasing interest. Thus, agri-food industry byproducts have emerged as a valuable source to obtain these hydrolysates as they are rich in proteins and inexpensive. Among these, byproducts from animal origin stand out as they are abundantly generated worldwide. Hence, this review is focused on evaluating the potential role of chicken slaughterhouse byproducts as a source of peptides for managing HTN. Several of these byproducts such as blood, bones, skins, and especially, chicken feet have been used to obtain protein hydrolysates with angiotensin-converting enzyme (ACE)-inhibitory activity and blood pressure-lowering effects. An increase in levels of endogenous antioxidant compounds, a reduction in ACE activity, and an improvement of HTN-associated endothelial dysfunction were the mechanisms underlying their effects. However, most of these studies were carried out in animal models, and further clinical studies are needed in order to confirm these antihypertensive properties. This would increase the value of these byproducts, contributing to the circular economy model of slaughterhouses.

Considerations on the Analysis of E-900 Food Additive: An NMR Perspective

Food additives are in widespread use in the food industry to extend the shelf life of food, improve its organoleptic characteristics or facilitate industrial processing. Their use is not without controversy, which makes regulation and control crucial for food safety and public health. Among food additives, silicone-based antifoaming agents (polysiloxanes or E900) are difficult to analyze and quantify due to their polymeric nature. Currently, there is no official method of quantifying this additive in foods. In this context, nuclear magnetic resonance (NMR) is a quantitative method for speciation analysis of silicon compounds almost without known interferents. In this work, we describe the evolution of the regulation of the E900 additive, discuss different analytic methods quantifying polydimethylsiloxanes (PDMS), and propose a new method based on NMR suitable for analyzing the content of E900 in the form of PDMS in various types of food from dietary oils to marmalades and jellies, among others. The proposed method consists of a previous quantitative concentration of PDMS by liquid-liquid extraction and the monitoring of the quantification using a bis(trimethylsilyl)benzene (BTMSB) standard to control the variability, ranging within 2-7%, depending on the food. This simple, direct, and reproducible procedure for aqueous and lipidic foods may help to monitor and fill a gap in regulatory legislation regarding the E900 additive.

A multifunctional ingredient for the management of metabolic syndrome in cafeteria diet-fed rats

The body weight-lowering properties of a multifunctional ingredient (MIX) based on conjugated linoleic acid at low doses, the flavonoids proanthocyanidins and anthocyanidins and the chicken feet hydrolysate Hpp11 have been previously reported. The aim of this study was to evaluate the effect of long-term administration of MIX on other cardiometabolic risk factors associated with metabolic syndrome (MetS) in rats fed a cafeteria diet (CAF). Male Wistar rats were fed CAF for 11 weeks, and during the last 3 weeks, animals were orally administered MIX or vehicle. Lipid tolerance tests were performed before and after MIX administration. At the end of the experimental period, serum and inguinal white adipose tissue (iWAT) metabolism were analyzed by metabolomics and biochemical approaches. The metabolite signature of serum and iWAT significantly changed after 3 weeks of MIX administration, suggesting an improvement in lipid and glucose homeostasis in these animals. In addition, MIX also exhibited significant antihypertensive properties. These results suggest that MIX could be a good candidate to ameliorate the cardiometabolic risk factors related to MetS.