Gut Micrbota and Its Relation to Anemia of CKD Patients Clinical Trial
Official title:
Relationship Between Gut Microbiota And Anemia In Patients With Chronic Renal Faliure
The human intestinal tract harbours a diverse and complex microbial community which plays a central role in human health. It has been estimated that our gut contains in the range of 1000 bacterial species and 100-fold more genes than are found in the human genome . This community is commonly referred to as our hidden metabolic 'organ' due to their immense impact on human wellbeing, including host metabolism, physiology, nutrition and immune function. It is now apparent that our gut microbiome coevolves with us and that changes to this population can have major consequences, both beneficial and harmful, for human health. Indeed, it has been suggested that disruption of the gut microbiota (or dysbiosis) can be significant with respect to pathological intestinal conditions such as obesity and malnutritio, systematic diseases such as diabetes and chronic inflammatory diseases such as inflammatory bowel disease (IBD), encompassing ulcerative colitis (UC) and Crohn's disease (CD) . The role of the gut microbiome in human health and disease is becoming clearer thanks to high throughput sequencing technologies (HTS) as well as parallel recent developments in non genomic techniques.
From the early stages of chronic kidney disease (CKD) there is a quantitative and qualitative alteration of intestinal microflora (dysbiosis); so the composition and metabolic activities of microflora are changed in CKD. These alterations include changes in intestinal transit, decreased protein absorption, decrease in dietary fibre intake, treatment with oral iron and frequent use of antibiotics. All of this contributes to systemic inflammation and the accumulation of uraemic toxins that are absorbed by intestine and eliminated by the kidney. This uraemic toxins have been associated with deleterious biological effects in different tissues and cell lines and with an increased risk of the progression of CKD, morbidity and mortality) - Progression of CKD: both indoxyl sulfate(IS) and p-cresyl sulfate (PCS) are associated to the development of fibrosis, deterioration of renal function and disease progression . In vitro studies have shown a deleterious effect of these molecules on renal tubular cells. - Cardiovascular complications: in CKD patients, IS is associated with endothelial damage, arterial stiffness and aortic calcification . - Anaemia: IS has been associated with anaemia of the renal patient; it interfere with the adequate production of erythropoietin and increased eryptosis (programmed cell death of red blood cells) .Polyamines are associated to anaemia in renal patients, through an intra-erythrocytic effect ,reduces erythropoiesis, and inhibit the activity of erythropoietin) - Alterations of bone-mineral metabolism: IS reduces bone formation by promoting oxidative stress in osteoblasts and inducing resistance to PTH, which favours the development a dynamic bone .There is a positive correlation between FGF-23 and IS serum levels, suggesting an association between this molecule and metabolic bone disease in uraemic patients . - Insulin resistance: In CKD patients the catabolism of insulin is reduced and often, they also have insulin resistance, which is associated with an increased risk of mortality; it seems that insulin resistance is related to some of the uremic toxins . ;