Nerve Guidance Conduits (NGCs) are crucial for reducing trauma during nerve repair, directing axonal growth, and preventing scar tissue formation. In this study, tubular functional NGCs were developed Show more
Nerve Guidance Conduits (NGCs) are crucial for reducing trauma during nerve repair, directing axonal growth, and preventing scar tissue formation. In this study, tubular functional NGCs were developed based on vertically aligned electrospun poly(lactic-co-glycolic acid) (PLGA) nanofibers (vNGC). They were functionalized by conjugating them with bioactive mimetic peptides: a laminin-derived peptide (LD-BP) to promote vascularization, and nerve growth factor (NGF-BP) and brain-derived neurotrophic factor (BDNF-BP) mimetic peptides to support neural differentiation. The vascular differentiation of HUVECs in response to LD-BP, and the neuronal differentiation of PC12 cells in response to NGF-BP and BDNF-BP, were assessed. The results demonstrated that this approach enabled the fabrication of tubular vNGCs with various diameters, and that vertically aligned PLGA nanofibers significantly improved their structural integrity. Furthermore, BP-conjugated vNGCs outperformed non-conjugated control groups in promoting both vascular and neural differentiation. Importantly, peptide conjugation did not induce cytotoxicity or significantly alter the biodegradability of the vNGCs, supporting their suitability for biomedical applications. Finally, bifunctional vNGCs (BiF-vNGCs), conjugated with LD-BP, NGF-BP, and BDNF-BP, were tested in a rat model of sciatic nerve injury. The BiF-vNGCs showed superior performance compared to unmodified vNGC, Control and s-Control groups, effectively promoting vascularization and neural regeneration in vivo, offering a viable alternative to conventional nerve regeneration methods. Show less
Juvenile idiopathic arthritis (JIA) is the most common childhood chronic arthritis, and pain may persist despite controlled inflammation, potentially due to central sensitization. This study aimed to Show more
Juvenile idiopathic arthritis (JIA) is the most common childhood chronic arthritis, and pain may persist despite controlled inflammation, potentially due to central sensitization. This study aimed to evaluate the effects of very early-onset arthritis on pain, behavior, and cognition using a collagen-induced arthritis model in juvenile rats. Thirty-six three-week-old male Wistar rats were divided into control, sham (saline), and arthritis (type II collagen with incomplete Freund's adjuvant) groups. Disease severity was monitored via joint thickness and VAS. Pain (hot plate, Randall-Selitto), behaviors (EPM, MFST), and cognition (PAT) were assessed. Locomotor activity was assessed. Joints were analyzed histologically (H&E); hippocampal BDNF and TNF-α were examined immunohistochemically. Arthritis severity progressed over six weeks, with increased joint thickness and VAS scores in the arthritis group (p < 0.05). Mechanical hyperalgesia showed a paw- and time-dependent pattern, with earlier changes in some paws and more consistent reductions during the late phase (weeks 4-6). Locomotor activity did not differ among groups, indicating no motor deficits. The arthritis group exhibited greater anxiety (EPM, p = 0.001) and depression-like behavior (FST, p = 0.004), while cognition (PAT) remained unaffected. Hippocampal TNF-α increased, whereas BDNF was unchanged. Very early-onset arthritis is associated with mechanical hyperalgesia and emotional disturbances, accompanied by hippocampal TNF-α alterations, and exhibits features consistent with central sensitization, without significant effects on cognition or hippocampal BDNF expression. Early juvenile arthritis showed mild severity with delayed mechanical hyperalgesia. Thermal hyperalgesia and locomotor deficits were not observed in arthritic rats. Hippocampal TNF-α increase was linked to anxiety and depression-like behaviors. Hippocampal BDNF levels remained stable, suggesting intact learning processes. Show less