Skeletal muscle dystrophies comprise a group of inherited disorders characterized by progressive muscle weakness, with Duchenne and Becker muscular dystrophies (DMD/BMD) being among the most severe. These dystrophies are caused by mutations in the dystrophin gene, resulting in muscle cell instability, chronic inflammation, fibrosis, and impaired muscle regeneration. Although skeletal muscle has intrinsic regenerative potential via satellite cells, the ongoing muscle damage in DMD/BMD depletes these cells and promotes fibrosis. Inflammation also plays a pivotal role, with immune cell infiltration correlating with disease severity. This study investigates fibrosis, inflammation, and capillarization in BMD patients across different age groups to clarify how disease progression varies over time. Morphological analyses of muscle biopsies revealed an increase in connective tissue, particularly in adult patients. Pediatric patients showed reduced capillarization, whereas adult patients displayed vascular adaptations, including elevated capillary-to-fibre ratios and capillary contacts, indicative of compensatory mechanisms in response to chronic muscle degeneration. Inflammatory profiles also varied with age: younger adult patients exhibited a predominance of CD68-positive macrophages, while older adults demonstrated increased CD4/CD8 T-cell activity. Our findings highlight pronounced age-dependent differences in muscle pathology, encompassing structural adaptations, fibrosis, and inflammation, which may be crucial for developing age-tailored therapeutic approaches.

In a susceptible individual, persistent, low-level injury to the airway epithelium initiates an exaggerated wound repair response, ultimately leading to idiopathic pulmonary fibrosis (IPF). The mechanisms driving this fibroproliferative response are not fully understood. Here, we review recent spatially resolved transcriptomics and proteomics studies that provide insight into two distinct matricellular microenvironments important in this pathological fibroproliferation. First, in response to alveolar epithelial injury, alveolar differentiation intermediate (ADI) basal cells arising from Secretoglobin (Scgb1a1) progenitors re-populate the injured alveolus remodeling the extracellular matrix (ECM). ADI cells exhibit an interconnected cellular stress response involving the unfolded protein response (UPR), epithelial-mesenchymal transition (EMT) and senescence pathways. These pathways reprogram cellular metabolism to support fibrillogenic ECM remodeling. In turn, the remodeled ECM tonically stimulates EMT in the ADI population, perpetuating the transitional cell state. Second, fibroblastic foci (FF) are a distinct microenvironment composed of activated aberrant "basaloid" cells supporting transition of adjacent mesenchyme into hyaluronan synthase (HAShi)-expressing fibroblasts and myofibroblasts. Once formed, FF are the major matrix-producing factories that invade and disrupt the alveolar airspace, forming a mature scar. In both microenvironments, the composition and characteristics of the ECM drive persistence of atypical epithelium sustaining matrix production. New approaches to monitor cellular trans-differentiation and matrix characteristics using positron emission tomography (PET)-magnetic resonance imaging (MRI) and optical imaging are described, which hold the potential to monitor the effects of therapeutic interventions to modify the ECM. Greater understanding of the bidirectional interrelationships between matrix and cellular phenotypes will identify new therapeutics and diagnostics to affect the outcomes of this lethal disease.

Immobilization-induced fibrosis is the primary pathogenesis of muscle contracture, and its trigger is myonuclear apoptosis. Tetanic exercise through electrical muscle stimulation may be able to mitigate myonuclear apoptosis; this could be an intervention strategy for Immobilization-induced fibrosis. In the present study, this was tested using rat skeletal muscles.

Rats were divided into the control, immobilization, low-contraction frequency (LCF), and high-contraction frequency (HCF) groups. The soleus muscles were used as specimens.

The number of TUNEL-positive myonuclei was 0.36 ± 0.11, 4.66 ± 0.90, 4.25 ± 0.99, and 1.90 ± 0.46 in the control, immobilization, LCF, and HCF groups, respectively. The HCF group was lower than the immobilization and LCF groups (all p < 0.001). The number of myonuclei and cross-sectional area (CSA) in the HCF group was higher than in the immobilization and LCF groups (all p < 0.001). The number of macrophages, mRNA expression of IL-1β, TGF-β1, and α-SMA, and hydroxyproline contents in the HCF group was lower than in the immobilization and LCF groups (all p < 0.001). There were moderate to strong negative correlations between the number of TUNEL-positive myonuclei and the number of myonuclei and between the CSA and the number of macrophages. Moderate to strong positive correlations were found between the number of myonuclei and the CSA, the number of macrophages and IL-1β, IL-1β and TGF-β1, TGF-β1 and α-SMA, and α-SMA and hydroxyproline contents.

Frequent tetanic exercise might mitigate macrophage accumulation caused by myonuclear apoptosis and suppress immobilization-induced muscle fibrosis due to fibrosis-associated molecule overexpression.

Bezafibrate (BZF) is a drug that reduces cholesterol and triglyceride levels in the blood. Research indicates that BZF, through activation of PPAR receptors, regulates the expression of genes involved in lipid homeostasis, inflammation, cell differentiation, and proliferation. This study investigated the in vitro and in vivo effects of BZF on activated hepatic stellate cells (HSCs) and on carbon tetrachloride-induced liver fibrosis in mice. After 72 h of treatment in vitro, BZF decreased cell proliferation, reversed the phenotype, decreased cell contraction, and induced autophagy. In addition, BZF promoted a protective effect on tetrachloride-induced liver fibrosis in mice, through antifibrotic actions. These findings suggest that BZF may have a potential antifibrotic effect, which could emerge as a possible new therapy for the treatment of liver fibrosis.

Cell sheet technology has been identified as a promising approach for the construction of tissue-engineered vascular grafts (TEVGs). However, concerns regarding immunogenicity and ethical issues, which are raised by the use of fetal bovine serum (FBS) in traditional culture systems, limit its potential for clinical translation. Serum-free medium (SFM) has emerged as a safer and more controllable alternative, but further validation is required to determine its effectiveness and superiority in generating high-quality cell sheets.

This study systematically compared cell sheets generated under SFM and 10% FBS culture conditions in terms of structure, cellular phenotype, and functional properties. The expression levels of α-SMA and SM22, markers of vascular smooth muscle cells(VSMCs), were evaluated using immunofluorescence staining, qRT-PCR, and Western blot analysis to assess cellular phenotype. Histological staining and mechanical testing were employed to compare the morphology and mechanical properties of the cell sheets, while extracellular matrix (ECM) deposition and biochemical characteristics were also analyzed.

Under SFM conditions, cells exhibited significantly higher α-SMA and SM22 expression levels (qRT-PCR showed a 1.8-fold and 2-fold increase, respectively; ****p < 0.0001) with clearer cytoskeletal arrangement. Cell sheets formed in SFM displayed comparable area(ns, p > 0.05), thickness(**p < 0.01), and mechanical properties to those cultured in 10% FBS, while ECM deposition was significantly enhanced (collagen content increased by approximately 40%, **p < 0.01). Furthermore, histological analysis revealed that cell sheets generated under SFM conditions were more compact and uniform, exhibiting superior structural organization.

SFM facilitates the generation of cell sheets that exhibit structural and functional properties analogous to those cultured in FBS. Additionally, SFM promotes cellular phenotype transition and ECM deposition. Consequently, SFM provides a safer, more controllable, and clinically translatable solution for cell sheet construction.

Aging is associated with a reduced number and function of muscle stem cells (MuSC). This results in a decreased muscle regenerative capacity and increased formation of fibrotic tissue, impairing skeletal muscle function. This review provides an overview of in vitro and in vivo animal studies investigating nutritional interventions with the potential to inhibit pathophysiological mechanisms involved in the development of skeletal muscle fibrosis. Mechanism targets include 1) MuSC function and myogenic differentiation, 2) M1 to M2 macrophage polarization, 3) myofibroblast activity or extracellular matrix (ECM) deposition, and 4) reactive oxygen species (ROS) mediated pathways, such as NOX2/4 activity. Most promising nutrients described in this review are phytonutrients, vitamins and amino acids. Quercetin targets multiple pathways (showing decreased inflammation, ECM expression and NOX2/4 activity) in various cell types and tissues (kidney, aorta, liver and (heart) muscle) of rodents and rabbits, which could contribute to fibrosis development. Additionally, sulforaphane is a promising candidate as it inhibits inflammation, ECM expression, and ROS production in mouse skeletal muscle. After validation of the effects in human skeletal muscle, supplementation with these nutrients could be implemented in a multifaceted intervention (including exercise and adequate protein intake) targeting age-related skeletal muscle fibrosis.

An expander capsule is a fibrous membrane that forms around a tissue expander. However, its outcome is still unclear. Here we investigated the biomechanical and histological outcomes of cervical capsules that were left in vivo after expanders were removed.

The deep and superficial capsules of 29 human cervical expanders were collected to serve as an experimental group. All 29 patients sustained facial and neck burn scars and underwent scar excision and expanded skin flap transfer. These capsules were divided into four groups based on the in vivo persistence time of the capsules following expander removal. The control group featured skin from five normal subjects. We investigated the biomechanics and histology of each group of capsules.

Capsule thickness, Young's modulus, collagen content, type I/III collagen ratio and α-SMA expression level were significantly related to the layer and the persistence time of the capsule in vivo (p＜0.05). Capsules persisted for more than 24 months following expander removal, the Young's modulus of the capsules remained greater than that of normal skin, limiting neck mobility. Moreover, some patients experience cord-like capsular contracture and a cervical pulling sensation, which may be attributable to the fusion of the deep expander capsules and platysma muscle.

Following the removal of neck expanders, the capsules can persist in vivo for a long time, affecting cervical contours and mobility.

This paper examines the physiological changes in spastic muscles contributing to spasticity and muscle stiffness, focusing on the underlying mechanisms and their clinical implications. Spasticity, which is prevalent in neurological conditions such as multiple sclerosis, cerebral palsy, spinal cord injury, stroke, and traumatic brain injury, is characterized by disordered sensorimotor control and often results in increased muscle stiffness and resistance to movement. Recent developments in the understanding of spasticity suggest the importance of architectural changes in muscles that may contribute to increased passive resistance, potentiate reflex mechanisms, and progression to fibrosis, with hyaluronan (HA), a glycosaminoglycan, playing a pivotal in modulating the properties of the muscle extracellular matrix (ECM). The hyaluronan hypothesis of muscle stiffness postulates that the accumulation and biophysical alteration of HA in the ECM of muscle increases its viscosity, resulting in increased passive mechanical resistance. This is turn mayincrease muscle sensitivity to stretch, potentiating spasticity, and lead to cellular differentiation of myofibroblasts to fibroblasts ultimately leading to fibrosis and contracture. A deeper understanding of HA's role in ECM dynamics offers promising avenues for novel treatments aimed at mitigating stiffness and preventing long-term disability in patients with spasticity.

Delayed tooth extraction socket (TES) healing can cause failure of subsequent oral implantation and increase socioeconomic burden on patients. Excessive amounts of M1 macrophages, apoptotic neutrophils (ANs), and neutrophil extracellular traps (NETs) impair alveolar bone regeneration during TES healing. In the present study, we first discovered that conditioned medium (CM) collected from berberine-treated human bone marrow mesenchymal stem cells (BBR-HB-CM) accelerated TES healing. BBR-HB-CM contained bioactive materials that promoted the polarization of macrophages from M1 to M2, impeded the formation of ANs and NETs, and modulated M2 macrophage efferocytosis in vivo and in vitro. Mechanistically, BBR-HB-CM promoted bone formation by inhibiting macrophage-myofibroblast transition and reprogrammed macrophage polarization through p85/AKT/mTOR pathway-dependent autophagy. The 3-methyladenine abolished the therapeutic effects of BBR-HB-CM. Further studies revealed that BBR-HB-CM accelerated TES healing in rats with type 2 diabetes mellitus. Overall, our results demonstrated that BBR-HB-CM had high potential to promote rapid TES healing.

Slow wound healing in the elderly has attracted much attention recently due to the associated infection risks and decreased longevity. The "brain-skin axis" theory suggests that abnormalities in the brain and nervous system can lead to skin degeneration because abnormal mental states, like chronic stress, can have negative physiological and functional effects on the skin through a variety of processes, resulting in delayed wound healing and accelerated skin aging. However, it remains unclear whether maintaining a youthful brain has beneficial effects on aged skin healing. In light of this, we identified youthful brain-derived extracellular vesicles (YBEVs) and created a composite GelMA hydrogel material that encourages scarless wound healing in aged skin. We found that YBEVs reduce the expression of senescence, senescence-associated secretory phenotypes, and inflammation-associated proteins, and even restore dysfunction in senescent cells. Furthermore, by encouraging collagen deposition, angiogenesis, epidermal and dermal regeneration, and folliculogenesis, we demonstrated that YBEV-containing composite hydrogels accelerated scarless wound healing in skin wounds of aged rats. The pro-repairing speed and effect of this composite hydrogel even matched that of young rats. Subsequent proteomic analysis revealed the presence of numerous proteins within YBEVs, some of which may play a role in the regulation of skin energy intake, particularly through oxidative phosphorylation and mitochondrial function. In conclusion, the findings suggest that maintaining a youthful brain could potentially alleviate skin aging, and the proposed YBEVs-GelMA hydrogel emerges as a promising strategy for addressing age-related impairments in skin healing.

Given the unique capabilities of natural cell membranes, such as prolonged blood circulation and homotypic targeting, extensive research has been devoted to developing cell membrane-inspired nanocarriers for cancer therapy, while most focused on overcoming one or a few biological barriers. In fact, the journey of nanosystems from systemic circulation to tumor cells involves intricate processes, encompassing blood circulation, tissue accumulation, cancer cell targeting, endocytosis, endosomal escape, intracellular trafficking to target sites, and therapeutic action, all of which pose limitations to their clinical translation. This underscores the necessity of meticulously considering these biological barriers in the design of cell membrane-mimetic nanocarriers. In this review, we delineate the functions and applications of diverse types of cell membranes in nanocarrier systems. We elaborate on the biological hurdles encountered at each stage of the biomimetic nanoparticle's odyssey to the target, and comprehensively discuss the obstacles imposed by the tumor microenvironment for precise delivery. Subsequently, we systematically review contemporary cell membrane-based strategies aimed at overcoming these multi-level biological barriers, encompassing hybrid cell membrane (HCM) camouflage, tumor microenvironment remodeling, endosomal/lysosomal escape, multidrug resistance (MDR) reversal, optimization of nanoparticle physicochemical properties, and so on. Finally, we outline potential strategies to accelerate the development of cell membrane-inspired precision nanocarriers and discuss the challenges that must be addressed to enhance their clinical applicability. This review serves as a guide for refining the study of cell membrane-mimetic nanosystems in surmounting in vivo delivery barriers, thereby significantly contributing to advancing the development and application of cell membrane-based nanoparticles in cancer delivery.

Previous studies have suggested that changes in the composition of the extracellular matrix (ECM) play a significant role in the development of ligamentum flavum hypertrophy (LFH) and the histological differences between the ventral and dorsal layers of the hypertrophied ligamentum flavum. Although LFH is associated with increased fibrosis in the dorsal layer, comprehensive research exploring the characteristics of the ECM and its mechanical properties in both regions is limited. Furthermore, the distribution of fibrosis-associated myofibroblasts within LFH remains poorly understood. This study aimed to bridge the existing knowledge gap concerning the intricate relationships between ECM characteristics, mechanical properties, and myofibroblast expression in LFH.

Histological staining, scanning electron microscopy, and atomic force microscopy were used to analyze the components, alignment, and mechanical properties of the ECM. Immunostaining and western blot analyses were performed to assess the distribution of myofibroblasts in LF tissues.

There were notable differences between the dorsal and ventral layers of the hypertrophic ligamentum flavum. Specifically, the dorsal layer exhibited higher collagen content and disorganized fibrous alignment, resulting in reduced stiffness. Immunohistochemistry analysis revealed a significantly greater presence of α-smooth muscle actin (αSMA)-stained cells, a marker for myofibroblasts, in the dorsal layer.

This study offers comprehensive insights into LFH by elucidating the distinctive ECM characteristics, mechanical properties, and cellular composition disparities between the ventral and dorsal layers. These findings significantly enhance our understanding of the pathogenesis of LFH and may inform future research and therapeutic strategies.

Fibrosis is a common late complication of radiation therapy. Molecular dysregulations leading to fibrosis have been characterized for the coding part of the genome, notably those involving the TGFB1 gene network. However, because a large part of the human genome encodes RNA transcripts that are not translated into proteins, exploring the involvement of the noncoding part of the genome in fibrosis susceptibility and development was the aim of this work.

Breast cancer patients having or not having developed severe breast fibrosis after radiation therapy were retrospectively selected from the COPERNIC collection. Exome sequencing and RNA-seq transcriptomic profiling were performed on 19 primary dermal fibroblast strains isolated from the patients' nonirradiated skin. Functional experiments were based on fibrogenic induction by transforming growth factor-Beta1 (TGFB1) and gene knockdown in healthy donor fibroblasts.

Coding and noncoding transcriptomes discriminated fibrosis from nonfibrosis conditions, and a signature of breast fibrosis susceptibility comprising 15 long noncoding RNAs (lncRNAs) was identified. A hazard ratio validation showed that the lncRNA vimentin antisense long noncoding RNA 1 (VIM-AS1) was the best biomarker associated with fibrosis risk. This lncRNA has not been previously associated with any fibrotic disorder, but we found it upregulated in data sets from cardiac fibrosis and scleroderma, suggesting a general role in tissue fibrosis. Functional experiments demonstrated a profibrotic action of VIM-AS1 because its knockdown reduced myofibroblast activation, collagen matrix production, and dermal organoid contraction. RNA-seq data analysis after VIM-AS1 silencing also pointed out the regulation of replication, cell cycle, and DNA repair. Mechanistically, because VIM-AS1 was found coregulated with the vimentin gene, these data support a profibrotic function of the TGFB1/VIM-AS1/vimentin axis, targeting the dynamics of fibroblast-myofibroblast transition.

Noncoding RNA analysis can provide specific biomarkers relevant to the prediction of normal tissue responses after radiation therapy, which opens perspectives of next-generation approaches for treatment, in the frame of the recent developments of RNA-based technologies.

Non-healing wounds are long-term complications of diabetes mellitus (DM) that increase mortality risk and amputation-related disability and decrease the quality of life. Nitric oxide (NO·)-based treatments (i.e., use of both systemic and topical NO· donors, NO· precursors, and NO· inducers) have received more attention as complementary approaches in treatments of DM wounds. Here, we aimed to highlight the potential benefits of NO·-based treatments on DM wounds through a literature review of experimental and clinical evidence. Various topical NO·-based treatments have been used. In rodents, topical NO·-based therapy facilitates wound healing, manifested as an increased healing rate and a decreased half-closure time. The wound healing effect of NO·-based treatments is attributed to increasing local blood flow, angiogenesis induction, collagen synthesis and deposition, re-epithelization, anti-inflammatory and anti-oxidative properties, and potent broad-spectrum antibacterial effects. The existing literature lacks human clinical evidence on the safety and efficacy of NO·-based treatments for DM wounds. Translating experimental favors of NO·-based treatments of DM wounds into human clinical practice needs conducting clinical trials with well-predefined effect sizes, i.e., wound reduction area, rate of wound healing, and hospital length of stay.

One of the major challenges in spatial transcriptomics is to detect spatially variable genes (SVGs), whose expression patterns are non-random across tissue locations. Many SVGs correlate with cell type compositions, introducing the concept of cell type-specific SVGs (ctSVGs). Existing ctSVG detection methods treat cell type-specific spatial effects as fixed effects, leading to tissue spatial rotation-dependent results. Moreover, SVGs may exhibit random spatial patterns within cell types, meaning an SVG is not always a ctSVG, and vice versa, further complicating detection. We propose STANCE, a unified statistical model for both SVGs and ctSVGs detection under a linear mixed-effect model framework that integrates gene expression, spatial location, and cell type composition information. STANCE ensures tissue rotation-invariant results, with a two-stage approach: initial SVG/ctSVG detection followed by ctSVG-specific testing. We demonstrate its performance through extensive simulations and analyses of public datasets. Downstream analyses reveal STANCE's potential in spatial transcriptomics analysis.

While improved screening rates have contributed to an overall decrease in the incidence of colorectal cancer (CRC), the incidence of early-age-onset CRC (EAO CRC; age <50 years) has increased. Here, we characterize the genetic alterations and tumor microenvironment (TME) for EAO and later-age-onset (LAO) CRCs to identify relevant biological differences that might point to etiologic factors.

A cohort of EAO (n = 60) and LAO (n = 93) CRC patients were evaluated for mutations by using targeted DNA sequencing and for TME differences by using immunohistochemistry and immunofluorescence. The Cancer Genome Atlas (TCGA) PanCancer Atlas colorectal adenocarcinoma cohort was evaluated for transcriptional changes between EAO (n = 82) and LAO (n = 510) patients.

KRAS and BRAF mutations were less frequent in EAO CRCs. Gene-set enrichment analysis of TCGA data revealed the downregulation of immune-related pathways in EAO CRCs. Both age cohorts had similar numbers of CD8+ tumor-infiltrating lymphocytes (TILs), although LAO patients had more CD4+ TILs and Th1-polarized CD4s. While significant associations between immune subsets and versican (VCAN), versikine, and alpha-smooth muscle actin (αSMA) were found, none of these trends differed between age cohorts. EAO patients trended towards greater VCAN accumulation in adjacent normal tissue, lower rates of VCAN proteolysis, and decreased αSMA accumulation vs LAO patients.

Overall, established EAO cancers are similar to LAO cancers in mutational profile and key TME features. High VCAN and αSMA expression in adjacent normal colon indicates a presence of factors that are associated with increased intestinal subclinical inflammation. Future mechanistic studies will be conducted to better understand the importance of these findings and related processes should be prioritized as potential etiologic factors for EAO tumorigenesis.

The intestine is a site of diverse functions including digestion, nutrient absorption, immune surveillance, and microbial symbiosis. Intestinal microRNAs (miRNAs) are detectable in faeces and regulate barrier integrity, host-microbe interactions and the immune response, potentially offering valuable non-invasive tools to study intestinal health. However, current experimental methods are suboptimal and heterogeneity in study design limits the utility of faecal miRNA data. Here, we develop an optimised protocol for faecal miRNA detection and report a reproducible murine faecal miRNA profile in healthy mice. We use this pipeline to study faecal miRNAs during infection with the gastrointestinal helminth, Trichuris muris, revealing roles for miRNAs in fibrosis and wound healing. Intestinal fibrosis was confirmed in vivo using Hyperion® imaging mass cytometry, demonstrating the efficacy of this approach. Further applications of this optimised pipeline to study host-microbe interactions and intestinal disease will enable the generation of hypotheses and therapeutic strategies in diverse contexts.

Keloids are complex pathological skin scars characterised by excessive growth of fibrous tissue and abnormal accumulation of extracellular matrix (ECM). Despite various treatment options available, the treatment of keloids remains a major clinical challenge due to high recurrence rates and inconsistent therapeutic outcomes. By collecting three keloid tissues and three normal skin samples and utilising single-cell RNA sequencing (scRNA-seq), we delved into the cellular heterogeneity and molecular mechanisms of keloids. Our study identified multiple fibroblast subpopulations within keloid tissue. Enrichment and cell-cell communication analyses revealed that POSTN-positive mesenchymal fibroblasts (POSTN+ mesenchymal fibs) are more prevalent in keloids and exhibit higher transforming growth factor β (TGF-β) signalling activity, potentially playing a central role in excessive fibrosis. In contrast, IGFBP2-positive fibroblasts (IGFBP2+ fibs) are more abundant in normal skin, insensitive to TGF-β and Periostin signalling, and possess anti-fibrotic potential, possibly related to limited tissue repair and regenerative capacity. Trajectory analysis inferred the differentiation states and patterns of different fibroblast subpopulations. Additionally, we explored the heterogeneity of endothelial cells, finding an endothelial cell subpopulation (EC10) exhibiting mesenchymal activation characteristics, which may work with specific fibroblasts to promote abnormal angiogenesis and endothelial-to-mesenchymal transition processes. Spatial transcriptomics analysis has shown that the proportion of IGFBP2+ fibroblasts relatively increases in acne keloidalis after hormonal treatment, further demonstrating their value as potential therapeutic targets. Ultimately, we separated these two subpopulations using flow cytometry, highlighting their opposing roles in the secretion of the ECM. These findings provide new insights into the pathogenesis of keloids and lay the theoretical foundation for the development of innovative anti-fibrotic treatment strategies.

Myofibroblasts, which play a crucial role in the tumour microenvironment, represent a promising avenue for research in the field of oncotherapy. This study investigates the potential for the induced differentiation of human fibroblasts into myofibroblasts through downregulation of the γ-cytoplasmic actin (γ-CYA) achieved by RNA interference. A decrease in the γ-CYA expression in human subcutaneous fibroblasts resulted in upregulation of myofibroblast markers, including α-smooth muscle actin (α-SMA), ED-A FN, and type III collagen. These changes were accompanied by notable alterations in cellular morphology, characterized by a significant increase in cell area and the formation of pronounced supermature focal adhesions. Downregulation of γ-CYA resulted in the compensatory increase in expression of the β-cytoplasmic actin and α-SMA, and formation of the characteristic α-SMA-positive stress fibers. In conclusion, our results demonstrate that a decrease in the γ-CYA expression leads to myofibroblastic trans-differentiation of human subcutaneous fibroblasts.

Skin innervation is very important for normal wound healing, and receptor activity-modifying protein 1 (RAMP1) has been reported to modulate calcitonin gene-related peptide (CGRP) receptor function and thus be a potential treatment target. This study aimed to elucidate the intricate regulatory effect of RAMP1 on skin fibroblast function, thereby addressing the existing knowledge gap in this area.

Immunohistochemical staining and immunofluorescence (IF) staining were used to measure the dynamic changes in the expression of RAMP1 and α-smooth muscle actin (α-SMA) in skin wound tissue in mice. Mouse skin fibroblasts (MSFs) stably transfected with Tet-on-Flag-RAMP1 overexpression (OE) and Tet-on-Flag control (Ctrl) lentiviruses were constructed for in vitro experiments. High mobility group AT-hook 1 (HMGA1) plasmids and α-SMA plasmids were used to overexpress HMGA1 and α-SMA, respectively. An α-SMA siRNA was used to silence α-SMA. Quantitative real-time polymerase chain reaction (qPCR), western blot and IF staining analyses were used to determine the mRNA and protein levels in the cells in different groups. A scratch wound healing assay was used to evaluate the cell migration ability of different groups. Cleavage under targets and release using nuclease (CUT & RUN) assays and dual-luciferase reporter assays were used to predict and verify the interaction between HMGA1 and the α-SMA promoter.

RAMP1 and α-SMA protein expression levels in the dermis changed dynamically and were negatively correlated during dorsal skin wound healing in mice. RAMP1 OE in vitro inhibited the differentiation and promoted the migration of MSFs by decreasing α-SMA expression via the suppression of HMGA1, which was shown for the first time to bind to the α-SMA promoter and increase α-SMA transcription. RAMP1 OE also modulated extracellular matrix (ECM) synthesis and remodeling by promoting collagen III and MMP9 expression and decreasing collagen I, MMP2, and tissue inhibitor of metalloproteinases 1 expression.

Our findings suggest that RAMP1 OE decreases differentiation and promotes migration in MSFs by downregulating α-SMA expression via the suppression of HMGA1 and modulates ECM synthesis and remodeling, revealing a novel mechanism regulating α-SMA transcription, providing new insights into the RAMP1-mediated regulation of fibroblast function, and identifying effective nerve-related targets for skin wound repair.

Obstructive sleep apnea (OSA) is increasingly recognized for its link to idiopathic pulmonary fibrosis (IPF), though the underlying mechanisms remain poorly understood. Histone lysine demethylase 6B (KDM6B) may either prevent or promote organ fibrosis, but its specific role in IPF is yet to be clarified. This study aimed to investigate the function and mechanisms of KDM6B in IPF and the exacerbating effects of OSA. We assessed KDM6B levels in lung tissues from IPF patients, IPF mouse models, and a dual-hit model combining OSA-associated intermittent hypoxia (IH) with bleomycin (BLM) or TGF-β1. We evaluated pulmonary fibrosis, myofibroblast activation, and oxidative stress. KDM6B levels were elevated in lung tissues from IPF patients and BLM-treated mice, as well as in TGF-β1-stimulated myofibroblasts. Importantly, IH significantly worsened BLM-induced pulmonary fibrosis and TGF-β1-induced myofibroblast activation, further amplifying KDM6B expression both in vivo and in vitro. Inhibition of KDM6B reduced pulmonary fibrosis and decreased fibroblast activation and migration in IPF and dual-hit models. Mechanistically, KDM6B inhibition led to decreased NOX4 expression and reduced oxidative stress. KDM6B plays a critical role in promoting pulmonary fibrosis and mediating the exacerbating effects of OSA on this condition. Our findings identify KDM6B as a novel potential therapeutic target for IPF.

Selenium (Se), a critically essential trace element, plays a crucial role in diverse physiological processes within the human body, such as oxidative stress response, inflammation regulation, apoptosis, and lipid metabolism. Organ fibrosis, a pathological condition caused by various factors, has become a significant global health issue. Numerous studies have demonstrated the substantial impact of Se on fibrotic diseases. This review delves into the latest research advancements in Se and Se-related biological agents for alleviating fibrosis in the heart, liver, lungs, and kidneys, detailing their mechanisms of action within fibrotic pathways. Additionally, the article summa-rizes some of the anti-fibrotic drugs currently in clinical trials for the aforementioned organ fibroses.

Mechanically regulated wound dressings require a rational combination of contraction and adhesion functions as well as balancing exudate-induced swelling issues. However, many of the reported dressings face the dilemma of impaired function and impeded wound self-contraction due to fluid-absorbing swelling. In this study, inspired by the tree ring, a core-ring structured hydrogel dressing capable of mechanical modulation is designed, and prepare it using a simple two-step photopolymerization process. The core covers the center of the wound, contracts spontaneously at body temperature to generate a contractile force of 3.4 kPa, and resists swelling. Meanwhile, the ring adheres to the normal epidermis around the wound and transfers the contraction stress to the wound edge. The integration of a functionally independent core and ring ultimately achieves effective wound traction and avoids dressing swelling. In murine and porcine skin wound-healing models, this hydrogel with a closely connected core and ring promotes healing by accelerating epidermal closure (50% closure in mouse skin on day 2, 85% closure in pig skin on day 8), collagen deposition, vascular maturation, and extracellular matrix remodeling. These results can guide further research on mechanical force modulation in wound healing, with the potential for clinical translation.

This study presents a novel in vitro bilayer 3D co-culture platform designed to obtain cancer-associated fibroblasts (CAFs)-like cells. The platform consists of a bilayer hydrogel structure with a collagen/polyethylene glycol (PEG) hydrogel for fibroblasts as the upper layer and an alginate hydrogel for tumor cells as the lower layer. The platform enabled paracrine interactions between fibroblasts and cancer cells, which allowed for selective retrieval of activated fibroblasts through collagenase treatment for further study. Fibroblasts remained viable throughout the culture periods and showed enhanced proliferation when co-cultured with cancer cells. Morphological changes in the co-cultured fibroblasts resembling CAFs were observed, especially in the 3D microenvironment. The mRNA expression levels of CAF-related markers were significantly upregulated in 3D, but not in 2D co-culture. Proteomic analysis identified upregulated proteins associated with CAFs, further confirming the transformation of normal fibroblasts into CAF within the proposed 3D co-culture platform. Moreover, co-culture with CAF induced radio- and chemoresistance in pancreatic cancer cells (PANC-1). Survival rate of cancer cells post-irradiation and gemcitabine resistance increased significantly in the co-culture setting, highlighting the role of CAFs in promoting cancer cell survival and therapeutic resistance. These findings would contribute to understanding molecular and phenotypic changes associated with CAF activation and provide insights into potential therapeutic strategies targeting the tumor microenvironment.

Myofibroblast differentiation, characterized by accumulation of cytoskeletal and extracellular matrix proteins by fibroblasts, is a key process in wound healing and pathogenesis of tissue fibrosis. Transforming growth factor-β (TGF-β) is the most powerful known driver of myofibroblast differentiation. TGF-β signals through transmembrane receptor serine/threonine kinases that phosphorylate Smad transcription factors (Smad2/3) leading to activation of transcription of target genes. Heterotrimeric G proteins mediate distinct signaling from seven-transmembrane G protein coupled receptors, which are not known to be linked to Smad activation. We tested whether G protein signaling plays any role in TGF-β-induced myofibroblast differentiation, using primary cultured human lung fibroblasts. Activation of Gαs by cholera toxin blocked TGF-β-induced myofibroblast differentiation without affecting Smad2/3 phosphorylation. Neither inhibition of Gαi by pertussis toxin nor siRNA-mediated combined knockdown of Gαq and Gα11 had a significant effect on TGF-β-induced myofibroblast differentiation. In contrast, combined knockdown of Gα12 and Gα13 significantly inhibited TGF-β-stimulated expression of myofibroblast marker proteins (collagen-1, fibronectin, smooth-muscle α-actin), with siGα12 being significantly more potent than siGα13. Mechanistically, combined knockdown of Gα12 and Gα13 resulted in substantially reduced phosphorylation of Smad2 and Smad3 in response to TGF-β, which was accompanied by a significant decrease in the expression of TGF-β receptors (TGFBR1, TGFBR2) and of Smad3. Thus, our study uncovers a novel role of Gα12/13 proteins in the control of TGF-β signaling and myofibroblast differentiation.

Wound healing as a result of a skin injury involves a series of dynamic physiological processes, leading to wound closure, re-epithelialization, and the remodeling of the extracellular matrix (ECM). The primary scar formed by the new ECM never fully regains the original tissue's strength or flexibility. Moreover, in some cases, due to dysregulated fibroblast activity, proliferation, and differentiation, the normal scarring can be replaced by pathological fibrotic tissue, leading to hypertrophic scars or keloids. These disorders can cause significant physical impairment and psychological stress and represent significant challenges in medical management in the wound-healing process. The present study aimed to investigate the therapeutic effects of exogenously applied carbon dioxide (CO2) on fibroblast behavior, focusing on viability, proliferation, migration, and differentiation to myofibroblasts. We found that CO2 exposure for up to 60 min did not significantly affect fibroblast viability, apoptosis rate, or proliferation and migration capacities. However, a notable finding was the significant reduction in α-smooth muscle actin (α-SMA) protein expression, indicative of myofibroblast differentiation inhibition, following CO2 exposure. This effect was specific to CO2 and concentration as well as time-dependent, with longer exposure durations leading to greater reductions in α-SMA expression. Furthermore, the inhibition of myofibroblast differentiation correlated with a statistically significantly reduced glycolytic and mitochondrial energy metabolism, and as a result, with a reduced ATP synthesis rate. This very noticeable decrease in cellular energy levels seemed to be specific to CO2 exposure and could not be observed in the control cultures using nitrogen (N2)-saturated solutions, indicating a unique and hypoxia-independent effect of CO2 on fibroblast metabolism. These findings suggest that exogenously applied CO2 may possess fibroblast differentiation-reducing properties by modulating fibroblast's energy metabolism and could offer new therapeutic options in the prevention of scar and keloid development.

To determine whether adjuvant transforming growth factor-β (TGF-β) inhibition with pirfenidone (PFD) can mitigate ureteral wall scarring and related complications in a rat model of upper urinary tract ablation with irreversible electroporation (IRE).

Transmural ablation of the ureter was performed with IRE in 24 rats. Post-IRE, animals were randomly assigned to receive PFD or no drug, followed by euthanasia at 2-, 5-, or 10-days. The complete urinary tract was extracted, and the dimensions of kidney and ureter were measured. Immunohistochemistry was performed to quantify collagen deposition, α-smooth muscle actin (α-SMA) (myofibroblasts in ureter and kidney) and TGF-β (ureter only).

Enlargement of the kidney and ureteral dilatation were apparent during gross necropsy of rats from both cohorts. The changes in anatomical measurements were significantly reduced in rats receiving PFD at Day 5 and 10 (p = 0.02 and 0.04, respectively). Collagen levels in the ureters gradually increased in rats from both cohorts at Day 2 and 5, but started to reduce by Day 10 in rats receiving PFD when compared with no treatment (p = 0.04). Myofibroblast levels and TGF-β staining in the ureters was lower in rats receiving PFD on Day 5 and 10, respectively (p < 0.01). Collagen levels and myofibroblast staining of the kidneys from rats receiving PFD was significantly lower than control on Days 5 and 10.

Adjuvant PFD can reduce myofibroblast activity and ureteral fibrosis at the site of IRE ablation, enabling safe soft tissue ablation adjacent or involving the upper urinary tract.

Submucosal fibrosis is associated with adverse events of endoscopic submucosal dissection (ESD). The present study mainly aimed to establish a predictive model for submucosal fibrosis in patients with early gastric cancer (EGC) undergoing ESD.

Eligible patients with EGC, identified at Qilu Hospital of Shandong University from April 2013 to December 2023, were retrospectively included and randomly split into a training set and a validation set in a 7:3 ratio. Logistic regression analyses were used to pinpoint the risk factors for submucosal fibrosis. A nomogram was developed and confirmed using receiver operating characteristic (ROC) curves, calibration plots, Hosmer-Lemeshow (H-L) tests, and decision curve analysis (DCA) curves. Besides, a predictive model for severe submucosal fibrosis was further conducted and tested.

A total of 516 cases in the training group and 220 cases in the validation group were recruited. The nomogram for submucosal fibrosis contained the following items: tumour location (long axis), tumour location (short axis), ulceration, and biopsy pathology. ROC curves showed high efficiency with an area under the ROC of 0.819 in the training group, and 0.812 in the validation group. Calibration curves and H-L tests indicated good consistency. DCA proved the nomogram to be clinically beneficial. Furthermore, the four items were also applicable for a nomogram predicting severe fibrosis, and the model performed well.

The predictive models, initially constructed in this study, were validated as convenient and feasible for endoscopists to predict submucosal fibrosis and severe fibrosis in patients with EGC undergoing ESD.

The apoptosis resistance of myofibroblasts is a hallmark in the irreversible progression of pulmonary fibrosis (PF). While the underlying molecular mechanism remains elusive. In this study, we unveiled a previously unrecognized mechanism underlying myofibroblast apoptosis resistance during PF. Our investigation revealed heightened expression of mesenchyme homeobox 1 (MEOX1) in the lungs of idiopathic pulmonary fibrosis (IPF) patients and bleomycin-induced PF mice. Silencing MEOX1 significantly attenuated PF progression in mice. In vitro, we found a notable increase in MEOX1 expression in transforming growth factor-β1 (TGF-β1)-induced myofibroblasts. Silencing MEOX1 enhanced apoptosis of myofibroblasts. Mechanistically, we identified G-protein signaling pathway regulatory factor 4 (RGS4) as a critical downstream target of MEOX1, as predicted by bioinformatics analysis. MEOX1 enhanced apoptosis resistance by upregulating RGS4 expression in myofibroblasts. In conclusion, our study highlights MEOX1 as a promising therapeutic target for protecting against PF by modulating myofibroblast apoptosis resistance.

Fibroblasts, the principal cellular mediators of connective tissue remodeling, play a crucial role in the formation of physiological and pathological scars. Understanding the intricate interplay between fibroblasts and other cellular and molecular components is essential for elucidating the underlying mechanisms driving scar formation. Hypertrophic scars, keloids and atrophic scars arise from dysregulated wound healing processes characterized by persistent inflammation, aberrant collagen deposition, and impaired extracellular matrix remodeling. Fibroblasts play a central role in the pathogenesis of such pathological scars, driving aberrant extracellular matrix remodeling, subsequently contributing to the formation of raised or depressed fibrotic lesions. The investigation of complex interactions between fibroblasts and the microenvironment is crucial for developing targeted therapeutic interventions aimed at modulating fibroblast activity and improving clinical outcomes in patients with pathological scars. Further research into the molecular pathways governing fibroblast behavior and their heterogeneity holds promise for advancing scar management strategies. This narrative review was performed to shed light on the mechanisms behind scar formation, with a special focus on the role of fibroblasts in the formation of different types of scars, providing insights into the pathophysiology of these conditions. Through the analysis of current knowledge, this review seeks to identify the key cellular and molecular mechanisms involved in fibroblast activation, collagen synthesis, and extracellular matrix remodeling in hypertrophic scar, keloid, or atrophic scar formation.

Inflammatory bowel diseases (IBD) and their sequela (colitis-associate carcinoma and fibrostenotic complications) remain a significant clinical challenge and novel therapeutic targets are desperately needed. AXL, a receptor tyrosine kinase, has been implicated in myriad cellular functions central to the pathogenesis of IBD. These include facilitating epithelial-to-mesenchymal transition, dampening of Toll-like receptor and natural killer cell mediated immune responses, driving proliferation, and propagating fibrogenic signaling. The vast majority of preclinical research on AXL has focused on its role in cancer. As such, pharmacologic AXL inhibitors are currently in clinical trials, but the indications remain limited to malignancy. In this chapter, we summarize the current preclinical data of AXL in IBD, colitis associated carcinoma, and fibrostenotic disease, and highlight its potential as a novel therapeutic target.

In recent observational studies, a potential link between prostatitis and prostate cancer (PCa) has been hinted at, yet the causality remains ambiguous. In our endeavor to scrutinize the conceivable causal nexus between prostatitis and PCa, we embarked upon a Mendelian randomization (MR) study. MR circumvents arbitrary groupings by employing genetic variations that have a strong association with the exposure as instrumental variables to infer causal relationships between exposures and outcomes. The etiology of PCa remains elusive. Given that prostatitis and prostate cancer occupy the same anatomical region, MR can more effectively delineate their relationship by mitigating confounding variables. This method can indirectly elucidate disease correlations, thereby contributing to cancer prevention strategies. FinnGen Consortium data were used for the prostatitis genome-wide association study (GWAS), including 74,658 participants. UK biobank baseline data (ncase = 3436, ncontrol = 459574), European Bioinformatics Institute Database (ncase = 79148, ncontrol = 61106), and IEU openGWAS database (ncase = 79148, ncontrol = 61106) were used for PCa outcomes, mostly for European population samples. Data from the GWSAs for prostatitis were compared with data from the three GWASs for PCa, respectively, in an analysis of an MR. Utilizing the inverse variance weighting (IVW) methodology as our primary analytical framework, we delved into a meticulous exploration of the conceivable causal association between prostatitis and PCa. Furthermore, we deployed supplementary methodologies, including Maximum Likelihood, MR-Egger, weighted median, and MR-PRESSO, to thoroughly assess and scrutinize the causality aspect comprehensively. Cochran's Q statistic is employed as a metric to quantify the heterogeneity inherent in instrumental variables. The inverse variance weighted analysis revealed no discernible effect of prostatitis on PCa in the three PCa GWAS databases (odds ratio [OR]: 1.001, 95% Confidence Interval [CI]: 0.999-1.002, p = 0.28), (OR: 1.015, 95% CI: 0.981-1.050, p = 0.40), (OR: 1.015, 95% CI: 0.981-1.050, p = 0.40). Similarly, employing MR-Egger did not yield substantial evidence (OR: 0.999, 95% CI: 0.999-1.002, p = 0.89), (OR: 1.103, 95% CI: 1.006-1.209, p = 0.07), (OR: 1.103, 95% CI: 1.006-1.209, p = 0.07). The weighted median analysis also failed to provide convincing support for the impact of prostatitis on the incidence of PCa (OR: 1.001, 95% CI: 1.000-1.002, p = 0.064), (OR: 0.989, 95% CI: 0.946-1.034, p = 0.64), (OR: 0.989, 95% CI: 0.945-1.036, p = 0.65). The results of the MR showed no causality from prostatitis to PCa.

Human periodontal ligament cells (hPDLCs) contain multipotent postnatal stem cells that can differentiate into PDL fibroblasts, osteoblasts, and cementoblasts. Interaction between the extracellular environment and stem cells is an important factor for differentiation into other progenitor cells. To identify cell surface molecules that induce PDL fibroblastic differentiation, we developed a series of monoclonal antibodies against membrane/ECM molecules. One of these antibodies, an anti-PDL25 antibody, recognizes approximately a 100 kDa protein, and this antigenic molecule accumulates in the periodontal ligament region of tooth roots. By mass spectrometric analysis, we found that the antigenic molecule recognized by the anti-PDL25 antibody is fibroblast activation protein α (FAPα). The expression level of FAPα/PDL25 increased in TGF-β1-induced PDL fibroblasts, and this protein was localized in the cell boundaries and elongated processes of the fibroblastic cells. Ectopic expression of FAPα induced fibroblastic differentiation. In contrast, expression of representative markers for PDL differentiation was decreased by knock down and antibody blocking of FAPα/PDL25. Inhibition of dipeptidyl peptidase activity by a potent FAPα inhibitor dramatically inhibited PDL fibroblastic marker expression but did not affect in cell proliferation and migration.

Macrophage-myofibroblast transformation (MMT) transforms macrophages into myofibroblasts in a specific inflammation or injury microenvironment. MMT is an essential biological process in fibrosis-related diseases involving the lung, heart, kidney, liver, skeletal muscle, and other organs and tissues. This process consists of interacting with various cells and molecules and activating different signal transduction pathways. This review deeply discussed the molecular mechanism of MMT, clarified crucial signal pathways, multiple cytokines, and growth factors, and formed a complex regulatory network. Significantly, the critical role of transforming growth factor-β (TGF-β) and its downstream signaling pathways in this process were clarified. Furthermore, we discussed the significance of MMT in physiological and pathological conditions, such as pulmonary fibrosis and cardiac fibrosis. This review provides a new perspective for understanding the interaction between macrophages and myofibroblasts and new strategies and targets for the prevention and treatment of MMT in fibrotic diseases.

Prostate cancer (PC) is an age-related disease and represents, after lung cancer, the second cause of cancer death in males worldwide. Mortality is due to the metastatic disease, which mainly involves the bones, lungs, and liver. In the last 20 years, the incidence of metastatic PC has increased in Western Countries, and a further increase is expected in the near future, due to the population ageing. Current treatment options, including state of the art cancer immunotherapy, need to be more effective to achieve long-term disease control. The most significant anatomical barrier to overcome to improve the effectiveness of current and newly designed drug strategies consists of the prostatic stroma, in particular the fibroblasts and the extracellular matrix, which are the most abundant components of both the normal and tumor prostatic microenvironment. By weaving a complex communication network with the glandular epithelium, the immune cells, the microbiota, the endothelium, and the nerves, in the healthy prostatic microenvironment, the fibroblasts and the extracellular matrix support organ development and homeostasis. However, during inflammation, ageing and prostate tumorigenesis, they undergo dramatic phenotypic and genotypic changes, which impact on tumor growth and progression and on the development of therapy resistance. Here, we focus on the characteristics and functions of the prostate associated fibroblasts and of the extracellular matrix in health and cancer. We emphasize their roles in shaping tumor behavior and the feasibility of manipulating and/or targeting these stromal components to overcome the limitations of current treatments and to improve precision medicine's chances of success.

The retina is a highly heterogeneous tissue, both cell-wise but also regarding its extracellular matrix (ECM). The stiffness of the ECM is pivotal in retinal development and maturation and has also been associated with the onset and/or progression of numerous retinal pathologies, such as glaucoma, proliferative vitreoretinopathy (PVR), age-related macular degeneration (AMD), epiretinal membrane (ERM) formation or uveitis. Nonetheless, much remains unknown about the biomechanical milieu of the retina, and specifically the role that Müller glia play as principal mechanosensors and major producers of ECM constituents. So far, new approaches need to be developed to further the knowledge in the field of retinal mechanobiology for ECM-target applications to arise. In this review, we focus on the involvement of Müller glia in shaping and altering the retinal ECM under both physiological and pathological conditions and look into various biomaterial options to more accurately replicate the impact of matrix stiffness in vitro.

The mechanism underlying intestinal fibrosis, the main complication of inflammatory bowel disease (IBD), is not yet fully understood, and there is no therapy to prevent or reverse fibrosis. We evaluated, in in vitro cellular models, the ability of different classes of drugs currently used in IBD to counteract two pivotal processes of intestinal fibrosis, the differentiation of intestinal fibroblasts to activated myofibroblasts using CCD-18Co cells, and the epithelial-to-mesenchymal transition (EMT) of intestinal epithelial cells using Caco-2 cells (IEC), both being processes induced by transforming growth factor-β1 (TGF-β1). The drugs tested included mesalamine, azathioprine, methotrexate, prednisone, methylprednisolone, budesonide, infliximab, and adalimumab. The expression of fibrosis and EMT markers (collagen-I, α-SMA, pSmad2/3, occludin) was assessed by Western blot analysis and by immunofluorescence. Of the drugs used, only prednisone, methylprednisolone, budesonide, and adalimumab were able to antagonize the pro-fibrotic effects induced by TGF-β1 on CCD-18Co cells, reducing the fibrosis marker expression. Methylprednisolone, budesonide, and adalimumab were also able to significantly counteract the TGF-β1-induced EMT process on Caco-2 IEC by increasing occludin and decreasing α-SMA expression. This is the first study that evaluates, using in vitro cellular models, the direct antifibrotic effects of drugs currently used in IBD, highlighting which drugs have potential antifibrotic effects.