Exercise-induced inflammation has been shown to influence iron metabolism. Conversely, ischemic preconditioning (IPC) has been proposed as a strategy to modulate post-exercise response, especially inf Show more
Exercise-induced inflammation has been shown to influence iron metabolism. Conversely, ischemic preconditioning (IPC) has been proposed as a strategy to modulate post-exercise response, especially inflammation and neurotrophic factor secretion. In this study we analyzed the effects of a 14-days IPC intervention on the post-exercises changes of the selected Iron metabolism, inflammation and neurotrophic markers in the population of non-training healthy young man. Forty healthy, untrained young men voluntarily participated in this study and were randomly assigned to two groups: an IPC group (n = 20), which underwent a 14-day IPC intervention, and a placebo (SHAM) group (n = 20). Five participants from the IPC group and seven from the SHAM group did not complete the protocol and were excluded from the analyzes. Venous blood samples were collected at rest, immediately after and 2 h after the Wingate test. Selected inflammatory and neurotrophic markers were analyzed, including IL-6, IL-10, IL-15, LIF, BDNF, IGF-1, NGF, sAPPα, FSTL-1, and GDF-15. Additionally, serum levels of iron (Fe), hepcidin (Hpc), ferritin (Fer), erythroferrone (ERFE), and erythropoietin (EPO) were assessed. IPC increased resting ferritin (~ + 9%, p < 0.05), hepcidin (~ + 12%, p < 0.05), and erythroferrone (~ + 10%, p < 0.05) concentrations. The intervention also enhanced post-exercise IGF-1 (+ 8%, p = 0.03) and sAPPα (+ 10%, p = 0.04) release and reshaped cytokine profiles, with greater early elevations of GDF-15 and IL-15 (p < 0.05) and faster normalization of FSTL-1 within 2 h (p < 0.05). IPC further affected neurotrophic signaling, showing lower 2-h post-exercise BDNF levels (p < 0.05) and distinct IGF-1 kinetics (p < 0.01). Anaerobic performance remained unchanged (p > 0.05). Ischemic preconditioning induces coordinated alterations in iron metabolism and modulates inflammatory and neurotrophic responses to anaerobic exercise, without affecting physical performance in untrained individuals. Show less
The key to proper implant integration in bone replacement is to orchestrate the complex interactions between materials and tissues. Moreover, due to the rapid demographic shift towards aging societies Show more
The key to proper implant integration in bone replacement is to orchestrate the complex interactions between materials and tissues. Moreover, due to the rapid demographic shift towards aging societies and the increase in elderly and osteoporotic patients, it is of great importance that implant materials are osteointegrative in not only healthy but also compromised bone tissues. Here, titanium (Ti) scaffolds were subjected to shifted laser surface texturing (sLST) using a nanosecond pulsed laser to create an open pore macrotopography with micro-and nano-Ti droplets. In contrast to conventional laser texturing, which leads to high heat accumulation; in sLST, the frequency of laser pulses is low, allowing for resolidification, thereby creating a surface with abundant coverage micro-/nanodroplets. The main objective was to compare the cellular responses of human mesenchymal stromal cells (hMSCs) on sLST-textured Ti surfaces (LT-Ti) for the first time with standard sand-blasted, acid-etched surfaces (SLA-Ti). In-depth analyses of cell survival, proliferation, shape, mineralization, and gene expression were performed. Cell survival/proliferation was found to be similar on both surfaces; however, SEM imaging revealed differences in hMSC morphology. On LT-Ti, cells adopted well-rounded shapes, whereas on SLA-Ti they assumed more planar shapes. Bulk RNA sequencing performed after short-term culture on both surfaces disclosed expression changes in genes such as Show less