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A hallmark of chronic kidney disease is the retention of solutes that normally are eliminated by the kidneys. The current classification defines uremic toxins based on molecular weight and protein affinity. The retention of solutes is already detected in the early stages of the disease when patients are pauci-symptomatic or asymptomatic but the role of therapies to retard the loss of kidney function in patients with chronic kidney disease (e.g., modulators of the renin-angiotensin-aldosterone system, sodium-glucose cotransporter inhibitors) in reducing uremic toxins is poorly understood. Most of the research evaluating the impact of therapies to lower serum concentrations of those toxic compounds is carried out in patients with kidney failure already undergoing kidney replacement therapy. The removal of those molecules relies in physicochemical mass transfer phenomena, i.e., adsorption, diffusion, and convection. In the past 2 decades, the rise and broad adoption of blood purification strategies with enhanced convective properties, such as high-volume online hemodiafiltration and expanded hemodialysis, considerably amplified the ability to mechanically extract middle molecules (molecular weight >0.5 kDa) from the blood compartment. Nonetheless, the classification of uremic toxins has not evolved in parallel with dialysis advancements. Mounting evidence demonstrates the link between middle molecules with uremic symptoms, cardiovascular and mortality risks. An urgent need for updating the classification exists. Defining the causative relationship between specific solutes and specific clinical outcomes will promote the development of targeted therapies. In parallel, the inclusion of new pertinent dimensions to the classification like the influence of new dialysis membranes, sorbents, and intestinal chelators in the concentration of uremic toxins would improve the understanding of the pathogenesis of chronic kidney disease, setting the pace for future research in nephrology.

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Parathyroid hormone (PTH) has an important role in the maintenance of serum calcium levels. It activates renal 1α-hydroxylase and increases the synthesis of the active form of vitamin D (1,25[OH]2D3). PTH promotes calcium release from the bone and enhances tubular calcium resorption through direct action on these sites. Hallmarks of secondary hyperparathyroidism associated with chronic kidney disease (CKD) include increase in serum fibroblast growth factor 23 (FGF-23), reduction in renal 1,25[OH]2D3 production with a decline in its serum levels, decrease in intestinal calcium absorption, and, at later stages, hyperphosphatemia and high levels of PTH. In this paper, we aim to critically discuss severe CKD-related hyperparathyroidism, in which PTH, through calcium-dependent and -independent mechanisms, leads to harmful effects and manifestations of the uremic syndrome, such as bone loss, skin and soft tissue calcification, cardiomyopathy, immunodeficiency, impairment of erythropoiesis, increase of energy expenditure, and muscle weakness.

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Abstract Introduction: Most uremic toxins are by-products of protein metabolism by action of intestinal flora. The metabolism of aromatic amino acids originates phenolic type residues. The most studied is p-cresol that is associated with renal function and vascular damage. Bisphenol A (BPA) is an exogenous molecule with characteristics similar to these aromatic uremic toxins. BPA is an estrogenic endocrine disruptor, found in tin cans, plastic bottles, epoxy resins and in some dialyzers. This molecule accumulates in patients who have impaired renal function. Observational studies have shown that exposure of BPA is linked to renal and cardiovascular injury, among many others in humans, and in animal studies a causal link has been described. Kidneys with normal renal function rapidly excrete BPA, but insufficient excretion in patients with CKD results in accumulation of BPA in the body.

Resumen Muchas toxinas urémicas son originadas como consecuencia del catabolismo proteico por la flora intestinal. El metabolismo de aminoácidos aromáticos origina residuos de tipo fenólico. De estas toxinas, la más estudiada es el p-cresol, que se asocia a la función renal y daño vascular. El Bisfenol A (BPA) es una molécula exógena de características semejantes a estas toxinas urémicas aromáticas. El BPA es un disruptor endocrino estrogénico que se encuentra en latas de conserva, botellas de plástico, resinas epoxi y en algunos dializadores. Esta molécula se acumula en pacientes que tienen deteriorada la función renal. Estudios observacionales han demostrado que una exposición a BPA está vinculada, entre otras muchas, a lesión renal y cardiovascular en los seres humanos; en estudios en animales se ha descrito un vínculo causal. Los riñones con función renal normal excretan rápidamente BPA, pero una excreción insuficiente en pacientes con ERC da lugar a la acumulación del BPA en el organismo.

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Recently, the clinical and experimental evidences that support the toxic effects of indoxyl sulfate, a protein-bound uremic toxin in chronic kidney disease (CKD) patients, has been discussed. In this panorama, the authors described several in vitro and in vivo studies, suggesting that indoxyl sulfate may play a part in the pathogenesis of low turnover bone disease. However, the discussion claims the need for relevant clinical studies in CKD patients whose bone turnover biomarkers and bone histomorphometry were assessed in order to demonstrate the association between serum levels of indoxyl sulfate and bone turnover. We would like to underline the availability of this clinical data to support the concept that indoxyl sulfate may play a part in the pathogenesis of low turnover bone disease in CKD patients.

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With over 100 trillion microbial cells, the gut microbiome plays important roles in both the maintenance of health and the pathogenesis of disease. Gut microbiome dysbiosis, resulted from alteration of composition and function of the gut microbiome and disruption of gut barrier function, is commonly seen in patients with chronic kidney disease (CKD). The dysbiotic gut microbiome generates excessive amounts of uremic toxins, and the impaired intestinal barrier permits translocation of these toxins into the systemic circulation. Many of these uremic toxins have been implicated in the progression of CKD and increased cardiovascular risk. Various therapeutic interventions have been proposed that aim to restore gut microbiome symbiosis. If proven effective, these interventions will have a significant impact on the management of CKD patients. In this review, we discuss the consequences of gut microbiome dysbiosis in the context of CKD, discuss the consequences of gut dysbiosis, and highlight some of the recent interventions targeting the gut microbiome for therapeutic purposes.

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Uremic toxins are compounds normally excreted in urine that accumulate in patients with chronic kidney disease as a result of decreased renal clearance. Phenylacetic acid (PAA) has been identified as a new protein bound uremic toxin. The purpose of this study was to investigate in vitro the interaction between PAA and human serum albumin (HSA) at physiological and pathological concentrations. We used ultrafiltration to show that there is a single high-affinity binding site for PAA on HSA, with a binding constant on the order of 3.4 × 10(4) M(-1) and a maximal stoichiometry of 1.61 mol per mole. The PAA, at the concentration reported in end-stage renal patients, was 26% bound to albumin. Fluorescent probe competition experiments demonstrated that PAA did not bind to Sudlow's site I (in subdomain IIA) and only weakly bind to Sudlow's site II (in subdomain IIIA). The PAA showed no competition with other protein-bound uremic toxins such as p-cresyl-sulfate or indoxyl sulfate for binding to serum albumin. Our results provide evidence that human serum albumin can act as carrier protein for phenylacetic acid.

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