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Molecular pathophysiology of chronic kidney disease–mineral and bone disorder: Focus on the fibroblast growth factor 23–Klotho axis and bone turnover dynamics

Abstract Chronic kidney disease–mineral and bone disorder (CKD-MBD) is a major complication of chronic kidney disease (CKD), characterized by disruptions in mineral metabolism, abnormal bone turnover and vascular calcification, which collectively increase the risk of fractures and cardiovascular disease. This review examines the molecular mechanisms underlying CKD-MBD, with a particular focus on the fibroblast growth factor 23 (FGF23)–Klotho axis – a key regulator of phosphate balance, vitamin D activation and parathyroid hormone secretion. In CKD, elevated FGF23 levels and reduced Klotho expression contribute to mineral homeostasis disturbances and bone abnormalities. The dysregulation of this pathway plays a central role in CKD-MBD pathophysiology and its associated complications.

Low Oxygen Concentration Enhances Chondrogenesis and Secretome Production in Mesenchymal Stem Cells Cultured in a Three-Dimentional Decellularized Bovine Cartilage Scaffolds

Abstract Introduction: Stem cells hold promise for tissue repair due to their secretome, which is influenced by the microenvironment. To improve cartilage regeneration, a three-dimensional (3D) natural cartilage scaffold system has been developed to create a more chondrogenic secretome. As human cartilage is avascular, a hypoxic environment may better mimic in vivo conditions. This study investigates if oxygen levels (normoxic vs. hypoxic) affect MSC chondrogenic potential and secretome composition in this 3D scaffold. Methods: This study used a randomized time series design to investigate how oxygen levels affect the transformation of MSCs into cartilage cells within a 3D cartilage scaffold. A control group (C) was grown in a standard medium. Two experimental groups, P1 and P2, were cultured n a 3D cartilage scaffold under normal (21%) and hypoxic (5%) oxygen concentration. respectively.

Natural Cartilage-Derived Scaffolds for 3D Mesenchymal Stem Cell Culture: Promoting Chondrogenesis and Modulating Secretome Composition

Abstract: Introduction: The regenerative potential of stem cells lies in their secretome, a collection of signaling molecules whose composition is shaped by the cellular microenvironment and external stimuli. To enhance cartilage regeneration, a 3D culture system using a natural cartilage scaffold has been developed to create a more chondrogenic secretome. This study investigates the chondrogenic differentiation of mesenchymal stem cells (MSCs) cultured in a decellularized bovine cartilage scaffold and analyzes the resulting secretome's composition. Methods: This study employed a randomized time series design to examine MSCs chondrogenic differentiation. A control group was cultured in standard 2D conditions, while two experimental groups were cultured in either 2D medium supplemented with chondrocyte differentiation medium (positive control) or a 3D decellularized bovine cartilage scaffold.

Ethyl Acetate Extract of Fungus Comb from Malayan Termite (Macrotermes Gilvus Hagen) Mound Modulates Splenic Inflammatory Responses in Mice

ABSTRACT Background: The fungus comb is a unique structure inside termites’ nests that facilitates the growth of Termitomyces sp. as a nutrient source for the termites. It is known to possess immunomodulatory properties that boost the immune system. Aim: The objective of this study was to assess the impact of ethyl acetate extract of fungus comb (EAEFC) on the inflammatory reaction in the spleen of mice induced by intraperitoneal injection of lipopolysaccharide (LPS). Methods: An experimental study was conducted using a post-test-only control group design with male BALB/C mice (n = 24). The mice were divided randomly into four groups, each comprising six mice, and administered substances via gavage. Groups I and III were administered a solution of 5% dimethyl sulfoxide (DMSO) in distilled water, while Groups II and IV were given 500 mg/kg BW EAEFC dissolved in 5% DMSO.

Selectively mixed matrix hemodialysis membrane for adequate clearance of p-cresol by the incorporation of imprinted zeolite

Abstract The adequacy in uremic toxin removal upon hemodialysis treatment is essential in patients with kidney failure diseases as poor removal leads to heart failure, hypertension, and stroke. The combination of adsorption and diffusion processes has become very advantageous for hemodialysis membranes. By this mechanism, water-soluble uremic toxins (WSUTs) and protein-bounded uremic toxins (PBUTs) could be removed at one time. Therefore, this study aimed to develop a novel imprinted zeolite by p-cresol (IZC) and then incorporated it into polyethersulfone (PES) and poly(vinyl pyrrolidone) (PVP) to produce hollow fiber mixed matrix membrane (HF-MMM). The IZC proved to be sensitive in attracting the adsorbate, classifying it as having a strong adsorption behavior.