RESUMO
Metabolic syndrome (MetS) is a multifactorial condition that significantly increases the risk of cardiovascular disease and chronic kidney disease (CKD). Recent studies have emphasized the role of lipid dysregulation in activating cellular mechanisms that contribute to CKD progression in the context of MetS. Sodium-glucose cotransporter 2 inhibitors (SGLT2i) have demonstrated efficacy in improving various components of MetS, including obesity, dyslipidemia, and insulin resistance. While SGLT2i have shown cardioprotective benefits, the underlying cellular mechanisms in MetS and CKD remain poorly studied. Therefore, this review aims to elucidate the cellular mechanisms by which SGLT2i modulate lipid metabolism and their impact on insulin resistance, mitochondrial dysfunction, oxidative stress, and CKD progression. We also explore the potential benefits of combining SGLT2i with other antidiabetic drugs. By examining the beneficial effects, molecular targets, and cytoprotective mechanisms of both natural and synthetic SGLT2i, this review provides a comprehensive understanding of their therapeutic potential in managing MetS-induced CKD. The information presented here highlights the significance of SGLT2i in addressing the complex interplay between metabolic dysregulation, lipid metabolism dysfunction, and renal impairment, offering clinicians and researchers a valuable resource for developing improved treatment strategies and personalized approaches for patients with MetS and CKD.
RESUMO
Diabetes mellitus (DM) is a chronic disease characterized by persistent hyperglycemia, which is a major contributing factor to chronic kidney disease (CKD), end-stage renal disease (ESRD), and cardiovascular-related deaths. There are several mechanisms leading to kidney injury, with hyperglycemia well known to stimulate oxidative stress, inflammation, tissue remodeling, and dysfunction in the vascular system and organs. Increased reactive oxygen species (ROS) decrease the bioavailability of vasodilators while increasing vasoconstrictors, resulting in an imbalance in vascular tone and the development of hypertension. Treatments for diabetes focus on controlling blood glucose levels, but due to the complexity of the disease, multiple drugs are often required to successfully delay the development of microvascular complications, including CKD. In this context, naringenin, a flavonoid found in citrus fruits, has demonstrated anti-inflammatory, anti-fibrotic, and antioxidant effects, suggesting its potential to protect the kidney from deleterious effects of diabetes. This review aims to summarize the scientific evidence of the effects of naringenin as a potential therapeutic option for diabetes-induced CKD.
RESUMO
Two siblings from a Mexican family who carried lethal Raine syndrome are presented. A newborn term male (case 1) and his 21 gestational week brother (case 2), with a similar osteosclerotic pattern: generalized osteosclerosis, which is more evident in facial bones and cranial base. Prenatal findings at 21 weeks and histopathological features for case 2 are described. A novel combination of biallelic FAM20C pathogenic variants were detected, a maternal cytosine duplication at position 456 and a paternal deletion of a cytosine in position 474 in exon 1, which change the reading frame with a premature termination at codon 207 and 185 respectively. These changes are in concordance with a negative detection of the protein in liver and kidney as shown in case 2. Necropsy showed absence of pancreatic Langerhans Islets, which are reported here for the first time. Corpus callosum absence is added to the few reported cases of brain defects in Raine syndrome. This report shows two new FAM20C variants not described previously, and negative protein detection in the liver and the kidney. We highlight that lethal Raine syndrome is well defined as early as 21 weeks, including mineralization defects and craniofacial features. Pancreas and brain defects found here in FAM20C deficiency extend the functional spectrum of this protein to previously unknown organs.