Organokines, Sarcopenia, and Metabolic Repercussions: The Vicious Cycle and the Interplay with Exercise.

Sarcopenia is a disease that becomes more prevalent as the population ages, since it is directly linked to the process of senility, which courses with muscle atrophy and loss of muscle strength. Over time, sarcopenia is linked to obesity, being known as sarcopenic obesity, and leads to other metabolic changes. At the molecular level, organokines act on different tissues and can improve or harm sarcopenia. It all depends on their production process, which is associated with factors such as physical exercise, the aging process, and metabolic diseases. Because of the seriousness of these repercussions, the aim of this literature review is to conduct a review on the relationship between organokines, sarcopenia, diabetes, and other metabolic repercussions, as well the role of physical exercise. To build this review, PubMed-Medline, Embase, and COCHRANE databases were searched, and only studies written in English were included. It was observed that myokines, adipokines, hepatokines, and osteokines had direct impacts on the pathophysiology of sarcopenia and its metabolic repercussions. Therefore, knowing how organokines act is very important to know their impacts on age, disease prevention, and how they can be related to the prevention of muscle loss.

Level of physical activity and gene expression of IL-10 and TNF-α in children and adolescents with Type 1 diabetes.

AIMS: The gene expressions of IL-10 and TNF-α have been identified as important factors of the clinical condition in type I diabetes mellitus (DM1). However, the effect of physical exercise on the expression of these markers is poorly understood. Our objective was to evaluate the relationship between the level of physical activity (LPA) and the gene expressions of IL-10 and TNF-α, as the relationship with glycemic control and insulin reserve in children and adolescents with DM1. METHODS: 108 participants (1-23 years), were divided into 4 groups: DM1 with ketoacidosis (KETO) (n = 15); Decompensated DM1 (DM1d) (n = 32); Compensated DM1 (DM1c) (n = 30); and healthy control (C) (n = 30). The level of physical activity (LPA) was classified as low active, active, and very active. So evaluated Fasting blood glucose, HbA1c, C-peptide, and gene expressions of IL-10 and TNF-α. RESULTS: The increase in the level of physical activity significantly affected the expression of TNF-α in the DMd and C groups. The increase in LPA from low to active reduced the gene expression of IL-10; however, the increase in NAF from active to very active was associated with an increase in IL-10 gene expression. A very active LPA contributes to reducing HbA1c and an increase in C-peptide in the KETO group. CONCLUSION: The increase in LPA demonstrated a significant effect on the improvement of IL-10 and TNF-α gene expression in the KETO and DMd groups; however, in the KETO group, improvements were also observed in the percentage of HbA1C and C-peptide.