Tissue Formation Research Articles

Light-based and cost-effective bioprinting of musculoskeletal GelMA constructs enriched with mesoporous bioactive glass nanoparticles

Bioprinting represents a promising technique for fabricating three-dimensional (3D) constructs with high-resolution and controlled architecture. However, many bioprinting technologies rely on expensive extrusion systems, which may compromise cell viability due to harsh processing conditions. This study presents the fabrication and characterization of musculoskeletal tissue in gelatin methacryloyl [GelMA]-based nanocomposite 3D constructs (comprising GelMA and mesoporous bioactive glass nanoparticles [MBGNs]) using a cost-effective, light-based bioprinting (LBB) system. We demonstrated that our strategy can produce high-resolution constructs (approximately 250 μm) while maintaining high cell viabilities (above 85%) for extended periods (weeks of culture). Furthermore, the nanocomposite constructs could facilitate the maturation of musculoskeletal tissue derived from C2C12 cells, as indicated by assessments of cell viability, elongation, and alignment over time. Our results suggested that the bioprinting approach outlined in this study allows for precise control of architecture, while creating a conducive environment for cell growth and tissue formation. These findings also highlighted the potential of the proposed LBB system to advance musculoskeletal tissue engineering for regenerative medicine applications.

Tunicate cellulose nanocrystal reinforced multifunctional hydrogel with super flexible, fatigue resistant, antifouling and self-adhesive capability for effective wound healing

Hydrogels as skin wound dressings have been extensively studied owing to their good flexibility and biocompatibility. Nevertheless, the mechanical performance, adhesive capability, antifouling and antibacterial properties of conventional hydrogels are still unsatisfactory, which hinder the application of hydrogel for cutaneous healing. Here, we developed a novel biocompatible multifunctional hydrogel with super flexible, fatigue resistant, antifouling and self-adhesive capability for effective wound healing, where naturally rigid polymers including quaternized chitosan (QCS) and Tunicate cellulose nanocrystals (TCNCs) are used as bioactive cross-linkers and reinforcers to endow the hydrogel with excellent mechanical and antibacterial property, and the synergistic contributions from the poly(acrylic acid/methacrylate anhydride dopamine/sulfobetaine methacrylate) (poly(AA/DMA/SBMA)) chains and QCS endow the hydrogel with excellent adhesive property, antioxidant, antifouling and pH-responsive sustained drug release capabilities. The optimized hydrogel exhibited high tensile strength (77.69 KPa), large tensile strain (889.9 %), large toughness (307.51KJ.m−3), high adhesive strength (35.57 KPa) and ideal compressive property. The in vivo infected full-thickness skin model demonstrated that the hydrogel with vanvomycin sustained release ability efficiently improved the granulation tissue formation, facilitating collagen deposition and reducing inflammatory expression, thus effectively accelerating wound healing. This superiorly skin-adhesive antibacterial biocompatible hydrogel appears to be a promising candidate for wound therapy.

Collagens of placenta composition in obese puerperant women who gave birth to сhildren at St. Petersburg State Pediatric Medical University in 2018–2021

BACKGROUND: The relevance of the problem of obesity is associated with the high frequency and steady growth of this pathology in the population. The epigenetic influence of maternal obesity on the course of pregnancy and childbirth, as well as on the condition of the fetus and newborn, is currently being studied. This article analyzes changes in the composition of the connective tissue of the placenta against the background of obesity in pregnant and puerperas. AIM: The aim of this study is to identify the pathomorphological features of the placenta and the composition of placental collagens in women who were obese before pregnancy and at the time of delivery at the Perinatal Center of St. Petersburg State Medical University from 2018 to 2021 to assess potential fetal risks and to predict possible complications during pregnancy and in the postnatal period for the mother. MATERIALS AND METHODS: A histological examination of the placentas of obese women (18 patients) and the ones with a normal body mass index (18 patients) who gave birth to mature newborns at the Perinatal Center of St. Petersburg State Medical University from 2018 to 2021 was performed followed by immunohistochemical examination. Staining of placenta specimens was carried out in accordance with the standard immunohistochemical protocol, using primary antibodies to type I–IV collagen. RESULTS: Microscopic examination of chorionic villi revealed no significant differences in the presence of chronic inflammation and angiogenesis disorders between the groups. When studying collagen expression levels, the following differences have been found: in the group of pregnant obese patients, the optical luminescence density and distribution area for type I–III collagen in the placenta were significantly higher, while for type IV collagen they were significantly lower compared with the control group. CONCLUSIONS: The following features of the formation of connective tissue in the placenta in obese mothers have been revealed: an increase in type I–III collagen production and a decrease in type IV collagen production. The obtained findings indicate an earlier functional and morphological change in the placenta than those detected by standard histological methods.

Nanofibrous dressing with drug/electroactivity synergistic effect for wound healing

Although electrical stimulation (ES) and drugs are desirable for wound healing, dressings that combine ES and drugs are scarce. In this study, an electroactive drug-loaded nanofibrous dressing (PUE-Zn/AB@CA) was prepared by loading zinc/acetylene black nanoparticle particles (Zn/AB) in Puerarin/cellulose acetate (PUE/CA) nanofibres, respectively. Due to the different potentials, many galvanic couples can be formed between Zn and AB, generating electrical stimulation that promotes cell migration and proliferation. Benefiting from the synergistic effect of Zn/AB electrical stimulation and PUE, PUE-Zn/AB@CA exhibits excellent antioxidant, antibacterial, and anti-inflammatory properties. The whole-layer wound defect model experiment showed that PUE-Zn/AB@CA can significantly accelerate wound closure and promote granulation tissue formation, collagen deposition, and angiogenesis at the wound. Moreover, PUE-Zn/AB@CA could inhibit the inflammatory infiltration of M1-type macrophages in damaged wounds. In addition, flow cytometry and Western blot (WB) revealed that PUE-Zn/AB@CA could effectively down-regulate the lipopolysaccharide (LPS)-induced macrophage polarisation towards M1-type and reduce the protein level of pro-inflammatory cytokines (iNOS) in the cells. This work provided an effective wound healing strategy based on drug/electroactivity synergistic effects.

Investigating the Effect of Carbon Nanomaterials Reinforcing Poly(ε-Caprolactone) Printed Scaffolds for Bone Repair Applications.

Scaffolds, three-dimensional (3D) substrates providing appropriate mechanical support and biological environments for new tissue formation, are the most common approaches in tissue engineering. To improve scaffold properties such as mechanical properties, surface characteristics, biocompatibility and biodegradability, different types of fillers have been used reinforcing biocompatible and biodegradable polymers. This paper investigates and compares the mechanical and biological behaviors of 3D printed poly(ε-caprolactone) scaffolds reinforced with graphene (G) and graphene oxide (GO) at different concentrations. Results show that contrary to G which improves mechanical properties and enhances cell attachment and proliferation, GO seems to show some cytotoxicity, particular at high contents.

Abstract We060: Hypoxia Inducible Factor-2α Enhances Neutrophil Survival and Promotes Cardiac Injury Following Myocardial Infarction via cIAP-1 Signaling

Rationale: Heart failure is a major cause of mortality following myocardial infarction (MI). Neutrophils (PMNs) are among the first immune cells to accumulate in the infarcted region. While some long-term beneficial functions of PMN in heart injury are now appreciated, en mase PMN accumulation in injured hearts is still associated with worsened resolution of inflammation and disease outcomes. MI causes extensive hypoxic injury to heart tissue, where hypoxia-inducible factors (HIFs) play critical roles in cellular functions. While HIF1α regulation of cell survival, migration and metabolism have been well-studied, the role of HIF-2α in these processes is not well-understood. Even less is known of HIF-2α contributions to PMN effector functions, especially in the context of MI. Objectives: The current study aimed to 1. Mechanistically explore how HIF-2α regulates survival of tissue infiltrating PMNs post-MI and 2. Determine how HIF-2α activity in PMNs impacts heart injury resolution post-MI, and whether specific HIF-2α deletion in PMNs can alleviate MI-induced tissue injury. Methods & Results: Infarct size, cardiac functions monitored by echocardiography, and scar tissue formation after left anterior descending coronary ligation injury model were compared between littermate control and specific PMN HIF-2α depletion (Ly6G-cre +/- HIF-2α fl/fl ) mice. Myocardial infarction size, cardiac dysfunction, scare tissue deposit and survival of tissue infiltrating PMNs post-MI were substantially attenuated in mice with PMN HIF-2α deletion. A significantly reduced lifespan of HIF-2α knockout PMNs was further confirmed by fate-mapping EdU pulse chase experiments. Mechanistically, molecular studies revealed that HIF-2α transcriptionally regulates expression of the pro-survival factor cIAP1 in PMNs binding to an HRE located in the promoter region of BIRC2 , in a hypoxia-inducible manner. Ex-vivo pharmacological inhibition of cIAP1 expression in PMNs using Birinapant resulted in dramatic cell death, establishing the critical role of cIAP1 in PMN survival. Finally, our data demonstrate that the protective effect of HIF-2α deletion in PMNs on MI outcomes was due to elevated recruitment of reparative macrophages into infarcted hearts. Conclusion: HIF-2α, through cIAP1 regulation, promotes PMN survival and tissue retention post-MI, leading to worsen cardiac functions and scar formation.

Expression of TGFβ-1 and CTGF in the Implanted Cochlea and its Implication on New Tissue Formation.

Transforming growth factor beta-1 (TGFβ-1) and connective tissue growth factor (CTGF) are upregulated in the implanted human cochlea. Cochlear implantation can lead to insertion trauma and intracochlear new tissue formation, which can detrimentally affect implant performance. TGFβ-1 and CTGF are profibrotic proteins implicated in various pathologic conditions, but little is known about their role in the cochlea. The present study aimed to characterize the expression of these proteins in the human implanted cochlea. Archival human temporal bones (HTB) acquired from 12 patients with previous CI and histopathological evidence of new tissue formation as well as surgical samples of human intracochlear scar tissue surrounding the explanted CI were used in this study. Histopathologic analysis of fibrosis and osteoneogenesis was conducted using H&E. Protein expression was characterized using immunofluorescence. RNA expression from surgical specimens of fibrotic tissue surrounding the CI was quantified using qRT-PCR. TGFβ-1 and CTGF protein expressions were upregulated in the areas of fibrosis and osteoneogenesis surrounding the CI HTB. Similarly, surgical samples demonstrated upregulation of protein and mRNA expression of TGFβ-1 and mild upregulation of CTGF compared with control. TGFβ-1 was expressed diffusely within the fibrous capsule, whereas CTGF was expressed in the thickened portion toward the modiolus and the fibrosis-osteoneogensis junction. To our knowledge, this is the first study to demonstrate increased expression of TGFβ-1 and CTGF in the human implanted cochlea and may provide better understanding of the mechanism behind this pathogenic process to better develop future mitigating interventions.

Migration and proliferation drive the emergence of patterns in co-cultures of differentiating vascular progenitor cells.

Vascular cells self-organize into unique structures guided by cell proliferation, migration, and/or differentiation from neighboring cells, mechanical factors, and/or soluble signals. However, the relative contribution of each of these factors remains unclear. Our objective was to develop a computational model to explore the different factors affecting the emerging micropatterns in 2D. This was accomplished by developing a stochastic on-lattice population-based model starting with vascular progenitor cells with the potential to proliferate, migrate, and/or differentiate into either endothelial cells or smooth muscle cells. The simulation results yielded patterns that were qualitatively and quantitatively consistent with experimental observations. Our results suggested that post-differentiation cell migration and proliferation when balanced could generate between 30-70% of each cell type enabling the formation of vascular patterns. Moreover, the cell-to-cell sensing could enhance the robustness of this patterning. These findings computationally supported that 2D patterning is mechanistically similar to current microfluidic platforms that take advantage of the migration-directed self-assembly of mature endothelial and mural cells to generate perfusable 3D vasculature in permissible hydrogel environments and suggest that stem or progenitor cells may not be fully necessary components in many tissue formations like those formed by vasculogenesis.

Identification of non-coding RNA signatures in idiopathic pulmonary fibrosis.

Idiopathic pulmonary fibrosis (IPF) is a deadly, chronic, progressive, irreversible interstitial lung disease characterized by the formation of scar tissue resulting in permanent lung damage. The average survival time following diagnosis is only 3-5years, with a 5-year survival rate shorter than that of many cancers. Alveolar epithelial cell injury followed by irregular repair is the primary pathological process observed in patients with IPF. An evident characteristic of IPF is the development of fibroblastic foci representing active fibrotic areas. Most of the cells within these foci are believed to be myofibroblasts, which are thought to be the primary source of abnormal extracellular matrix production in IPF. The lung phenotype in IPF is characterized by significantly different processes from healthy lungs, including irregular apoptosis, oxidative stress, and epithelial-mesenchymal transition (EMT) pathways. The exact cause of IPF is not fully understood and remains mysterious. It is not suppressing that non-coding RNAs are involved in the development and progression of IPF. Accordingly, here we aimed to identify non-coding RNA molecules during TGFβ-induced myofibroblast activation. Differential expression and functional enrichment analysis were employed to reveal the impact of non-coding RNAs during TGFβ-associated lung fibrosis. Remarkably, LOC101448202, CZ1P-ASNS, LINC01503, IER3-AS1, MIR503HG, CLMAT3, LINC02593, ACTA2-AS1, LOC102723692, LOC107985728, and LOC105371064 were identified to be differentially altered during TGFβ-stimulated myofibroblast activation. These findings strongly suggest that the mechanism of lung fibrosis is heavily under control of non-coding RNAs, and RNA-based therapies could be a promising approach for future therapeutic interventions to lung fibrosis.

Dynamic regulation of innate lymphoid cell development during ontogeny

The helper-like ILC contains various functional subsets, such as ILC1, ILC2, ILC3 and LTi cells, mediating the immune responses against viruses, parasites, and extracellular bacteria, respectively. Among them, LTi cells are also crucial for the formation of peripheral lymphoid tissues, such as lymph nodes. Our research, along with others’, indicates a high proportion of LTi cells in the fetal ILC pool, which significantly decreases after birth. Conversely, the proportion of non-LTi ILCs increases postnatally, corresponding to the need for LTi cells to mediate lymphoid tissue formation during fetal stages and other ILC subsets to combat diverse pathogen infections postnatally. However, the regulatory mechanism for this transition remains unclear. In this study, we observed a preference for fetal ILC progenitors to differentiate into LTi cells, while postnatal bone marrow ILC progenitors preferentially differentiate into non-LTi ILCs. Particularly, this differentiation shift occurs within the first week after birth in mice. Further analysis revealed that adult ILC progenitors exhibit stronger activation of the Notch signaling pathway compared to fetal counterparts, accompanied by elevated Gata3 expression and decreased Rorc expression, leading to a transition from fetal LTi cell-dominant states to adult non-LTi ILC-dominant states. This study suggests that the body can regulate ILC development by modulating the activation level of the Notch signaling pathway, thereby acquiring different ILC subsets to accommodate the varying demands within the body at different developmental stages.

Production of platelet-rich plasma (PRP)-enriched scaffolds for bone tissue regeneration with 3D printing technology

Bone disorders signify diverse abnormalities in the structure, development, and functions of bone tissue in the human body, with a significant correlation to ageing, insufficient physical activity, and escalating obesity. Recent advancements in bone tissue engineering aim to enhance bone tissue formation through the use of biomaterials, growth factors, and cells. The present study focuses on the fabrication and characterisation of scaffolds with a composition of gelatin (GEL) / sodium alginate (SA) / hydroxyapatite (HA) / platelet-rich plasma (PRP) using the 3D printing process. The inclusion of PRP, derived from blood, is of particular interest due to its potential to enhance bone regeneration through various growth factors. Scanning electron microscope (SEM) analysis revealed average pore sizes ranging from 481.50 ± 7.65 to 623.96 ± 11.54 µm. SEM images also showed that scaffold surfaces became smooth as the concentration of PRP increased. The mechanical test results demonstrated that as the PRP increased, the compressive strength decreased. When the swelling and degradation behaviours of scaffolds were examined, it was observed that GEL/SA/HA/3PRP scaffolds exhibited approximately 200 % swelling capability until the 4th day. GEL/SA/HA scaffolds showed a degradation behaviour about 70 % higher compared to other groups. A controlled release profile of PRP was maintained up to the 144th, 216th, and 240th hours from the scaffolds. According to the highest correlation coefficients (R2) in the release kinetics of scaffolds, GEL/SA/HA/0.5PRP and GEL/SA/HA/1PRP scaffolds were explained by the first-order model. In contrast, the GEL/SA/HA/3PRP scaffold was described using the Korsmeyer–Peppas model. The MTT analysis conducted with osteoblast cells showed that scaffolds did not demonstrate any toxic effects and facilitated cell adhesion by inducing the formation of extensions. These findings underscore the potential of PRP-incorporated GEL/SA/HA composites as a promising approach for bone tissue engineering, offering significant advancements in the treatment of bone disorders. This could lead to more effective treatments for bone disorders and injuries, reducing the need for more invasive procedures and improving patient recovery times.

Effects of Synthetic Toll-Like Receptor 9 Ligand Molecules on Pulpal Immunomodulatory Response and Repair after Injuries.

Synthetic oligodeoxynucleotides (ODNs) containing unmethylated cytosine-phosphate-guanine (CpG) motifs (CpG-ODNs) are ligand molecules for Toll-like receptor 9 (TLR9), which is expressed by odontoblasts in vitro and dental pulp cells. This study determined the effects of CpG-ODNs on pulpal immunomodulatory response and repair following injury. Briefly, the upper right first molars of three-week-old mice were extracted, immersed in Type A (D35) or B (K3) CpG-ODN solutions (0.1 or 0.8 mM) for 30 min, and then replanted. Pulpal healing and immunomodulatory activity were assessed by hematoxylin-eosin and AZAN staining, as well as immunohistochemistry. One week following the operation, inflammatory reactions occurred in all of the experimental groups; however, re-revascularization and newly formed hard tissue deposition were observed in the pulp chamber of all groups at week 2. A positive trend in the expression of immune cell markers was observed toward the CpG-ODN groups at 0.1 mM. Our data suggest that synthetic CpG-ODN solutions at low concentrations may evoke a long-lasting macrophage-TLR9-mediated pro-inflammatory, rather than anti-inflammatory, response in the dental pulp to modulate the repair process and hard tissue formation. Further studies are needed to determine the effects of current immunomodulatory agents in vitro and in vivo and develop treatment strategies for dental tissue regeneration.

Micron-scale topographies affect phagocytosis of bacterial cells on polydimethylsiloxane surfaces

Many medical devices implanted in patients to mitigate diseases and medical conditions have different types of topographic features. While appropriate textures can promote the integration of host cells and reduce scar tissue formation, some textured implants with inappropriate topographies have been associated with inflammation, bacterial colonization, or even malignant complications. To better understand how surface topography affects host immune response to colonizing bacteria, a protocol was developed to investigate phagocytosis of bacterial cells attached on polydimethylsiloxane (PDMS) surfaces with different square-shaped recessive patterns. The interaction between activated RAW 264.7 macrophages and Escherichia coli in recessive wells was visualized in 3D using multiple fluorescent markers. The results revealed that there is a threshold dimension of topography, below which phagocytosis of attached bacterial cells is significantly impeded. Specifically, under our experimental condition, up to 100-fold reduction in phagocytosis was observed in square-shaped patterns with 5 µm side length and 10 µm depth compared to the flat control and patterns with 10 µm or longer side length. The spacing between wells also showed significant effects; e.g., phagocytosis in the wells further decreased when spacing increased to 50 µm. These results are helpful for understanding how undesired topographies may contribute to bacterial colonization and thus infection and other associated complications. Statement of significanceSurface topography plays an important role in bacteria-material infections and thus the safety of implantable medical devices. Undesired topographic features can cause biofilm formation and related complications. However, how surface topography affects the capability of host immune cells to clear colonizing bacteria is not well understood. In this study, the interaction between macrophage RAW264.7 and colonizing E. coli cells on polydimethylsiloxane (PDMS) with recessive features is investigated. It was discovered that the size of recessive features and the spacing between these features have significant effects on phagocytosis of bacteria by macrophages. These new results are helpful for understanding the complex interaction among host cells, bacteria, and implanted biomaterials, which will help guide the rational design of safer medical devices.

Osteogenic potency of dental stem cell-composite scaffolds in an animal cleft palate model

ObjectiveTo evaluate the osteogenic potency of stem cells isolated from human exfoliated deciduous teeth (SHED) in polycaprolactone with gelatin surface modification (PCL-GE) and poly (lactic-co-glycolic acid)-bioactive glass composite (PLGA-bioactive glass (BG)) scaffolds after implantation in a rat cleft model. MethodsCleft palate-like lesions were induced in Sprague-Dawley rats by extracting the right maxillary first molars and drilling the intact alveolar bone. Rats were then divided into five groups: Control, PCL-GE, PCL-GE-SHED, PLGA-BG, and PLGA-BG-SHED, and received corresponding composite scaffolds with/without SHED at the extraction site. Tissue samples were collected at 2, 3, and 6 months post-implantation (4 rats per group). Gross and histological analyses were conducted to assess osteoid or bone formation. Immunohistochemistry for osteocalcin and human mitochondria was performed to evaluate bone components and human stem cell viability in the tissue. ResultsBone tissue formation was observed in the PCL-GE and PLGA-BG groups compared to the control, where no bone formation occurred. PLGA-BG scaffolds demonstrated greater bone regeneration potential than PCL-GE over 2–6 months. Additionally, scaffolds with SHED accelerated bone formation compared to scaffolds alone. Osteocalcin expression was detected in all rats, and positive immunoreactivity for human mitochondria was observed in the regenerated bone tissue with PCL-GE-SHED and PLGA-BG-SHED. ConclusionPCL-GE and PLGA-BG composite scaffolds effectively repaired and regenerated bone tissue in rat cleft palate defects. Moreover, scaffolds supplemented with SHED exhibited enhanced osteogenic potency. Clinical significancePCL-GE and PLGA-BG scaffolds, augmented with SHED, emerge as promising biomaterial candidates for addressing cleft repair and advancing bone tissue engineering endeavors.

Unveiling the governing role of ‘remodeling triangle area’ in soft-hard tissue interface equilibrium for metal implants advancement

Metal implants holds significant promise for diverse fixed prostheses. However, their long-term reliability and broader application are hindered by challenges related to the disequilibrium at the soft-hard tissue interface. By using anti-inflammatory (PDA/IL4) and pro-inflammatory (PDA/LPS/IFNγ) coatings to modulate distinct immune characteristics, we discovered a dynamic bioactive structure at the soft-hard tissue interface around metal implant, which we have named the 'Remodeling Triangle Area' (RTA). We further demonstrate that the RTA can be influenced by the PDA/IL4 coating to favor a phenotype that enhances both innate and adaptive immunity. This leads to stronger epithelial adhesion, the formation of dense connective tissue via IGF1 secretion, and a more balanced soft-hard tissue interface through the OPG/RANKL axis. Conversely, the PDA/LPS/IFNγ coating shifts the RTA towards a phenotype that activates the innate immune response. This results in a less cohesive tissue structure and bone resorption, characterized by reduced IGF1 secretion and an imbalanced OPG/RANKL axis. Over all, our study introduces the novel concept termed the 'Remodeling Triangle Area' (RTA), an immune-rich anatomical region located at the nexus of the implant interface, epithelial, connective, and bone tissue, which becomes highly interactive post-implantation to modulate the soft-hard tissue interface equilibrium. We believe that an RTA-centric, immunomodulatory approach has the potential to revolutionize the design of next-generation metal implants, providing unparalleled soft-hard tissue interface equilibrium properties.

Gold nanoclusters on a silk fibroin scaffold accelerate fibroblast proliferation and improve burn recovery in a mouse burn model

Delayed wound healing in skin burn injuries is common owing to inhibition of proliferation caused by excessive inflammation, necrosis, autophagy, and oxidative stress. Gold nanoclusters modified with lipoic acid (AuNCs) exhibited antioxidant and anti-inflammatory effects in a murine burn healing model. However, the impact of the AuNCs on dermal cell proliferation and granulation tissue formation remains unclear. We therefore examined their effects on dermal cell proliferation, the cell cycle, and the signaling pathways involved. AuNCs were combined with a silk fibroin scaffold and tested in a mouse burn model and human dermal fibroblasts in vitro. Combined with the silk fibroin scaffold, 50 nmol/L of AuNCs activated fibroblast differentiation, collagen deposition, and angiogenesis, increasing granulation-tissue formation, reducing tissue necrosis and systemic inflammatory response, and improving wound healing in the model. The AuNCs increased PI3K/Akt signaling pathway phosphorylation in human dermal fibroblasts, upregulating protein expression of cyclin A, B, and CDK1, which participate in the G2/M cell cycle phase, ultimately promoting fibroblast proliferation. These findings support the beneficial effects of AuNCs on burn wound healing. We suggested that AuNCs on a silk fibroin scaffold or other vector is a potential clinical strategy for burn wound treatment.

Using Laponite to Deliver BMP‐2 for Bone Tissue Engineering – In Vitro, Chorioallantoic Membrane Assay and Murine Subcutaneous Model Validation

AbstractFracture non‐union occurs due to various factors, leading to the development of potentially substantial bone defects. While autograft and allograft are the current gold standards for non‐union fractures, challenges related to availability and immune rejection highlight the need for improved treatments. A strategy in bone tissue engineering is to harness growth factors to induce an effect on cells to change their phenotype, behavior and initiate signaling pathways which lead to increased matrix deposition and tissue formation. Bone morphogenetic protein‐2 (BMP‐2) is a potent osteogenic growth factor however, given its rapid clearance time in vivo, there is a specific therapeutic window for efficacy while avoiding potential deleterious side‐effects. It is demonstrated that a Laponite nanoclay coating on a 3D printable and bioresorbable poly(caprolactone) trimethacrylate‐based resin enables binding of BMP‐2, decreases the rate of release, enabling reduced concentrations to be used while enhancing osteoinduction in both in vitro and in vivo models.

Expression of Osteopontin and Gremlin 1 Proteins in Cardiomyocytes in Ischemic Heart Failure.

A relevant role of osteopontin (OPN) and gremlin 1 (Grem1) in regulating cardiac tissue remodeling and formation of heart failure (HF) are documented, with the changes of OPN and Grem1 levels in blood plasma due to acute ischemia, ischemic heart disease-induced advanced HF or dilatative cardiomyopathy being the primary focus in most of these studies. However, knowledge on the early OPN and Grem1 proteins expression changes within cardiomyocytes during remodeling due to chronic ischemia remains insufficient. The aim of this study was to determine the OPN and Grem1 proteins expression changes in human cardiomyocytes at different stages of ischemic HF. A semi-quantitative immunohistochemical analysis was performed in 105 myocardial tissue samples obtained from the left cardiac ventricles. Increased OPN immunostaining intensity was already detected in the stage A HF group, compared to the control group (p < 0.001), and continued to increase in the stage B HF (p < 0.001), achieving the peak of immunostaining in the stages C/D HF group (p < 0.001). Similar data of Grem1 immunostaining intensity changes in cardiomyocytes were documented. Significantly positive correlations were detected between OPN, Grem1 expression in cardiomyocytes and their diameter as well as the length, in addition to positive correlation between OPN and Grem1 expression changes within cardiomyocytes. These novel findings suggest that OPN and Grem1 contribute significantly to reorganization of cellular geometry from the earliest stage of cardiomyocyte remodeling, providing new insights into the ischemic HF pathogenesis.

Cfhr1 gene deficiency exacerbates Staphylococcus aureus-induced sepsis and acute lung injury through complement alternative pathway hyperactivation

ObjectiveTo explore the role of excessive activation of the complement alternative pathway (AP) in acute lung injury (ALI) and sepsis induced by Staphylococcus aureus. Subsequently, we aimed to define the effects of Cfhr gene deletion on Factor H expression, AP activation, and the development of sepsis-induced ALI. MethodsA sepsis-induced ALI model was established in Cfhr1-knockout mice by tail vein injection of S. aureus. Sepsis scores, bacterial load in lungs, and cytokine and complement factor levels in blood and lung tissues were evaluated at 6, 12, and 24 h after model establishment. Real-time quantitative PCR and RNA sequencing (RNA-seq) were employed to assess the expression of complement pathway-associated molecules and identify differentially expressed genes (DEGs) related to immune responses. ResultsCompared to wild-type mice, Cfhr1-knockout mice exhibited significantly increased C3a formation in lung tissues following S. aureus infection, indicating enhanced terminal complement pathway activation. Notably, these mice also had higher bacterial colony counts in the lungs, suggesting impaired S. aureus clearance. Transcriptome analysis provided further insights into the impact of Cfhr1 deletion on biological processes and signalling pathways involved in immune response regulation. ConclusionCfhr1 deletion leads to excessive AP activation, exacerbating S. aureus-induced sepsis and ALI.

MLPH is a novel adipogenic factor controlling redox homeostasis to inhibit lipid peroxidation in adipocytes

Abnormal adipose tissue formation is associated with metabolic disorders such as obesity, diabetes, and liver and cardiovascular diseases. Thus, identifying the novel factors that control adipogenesis is crucial for understanding these conditions and developing targeted treatments. In this study, we identified the melanosome-related factor MLPH as a novel adipogenic factor. MLPH was induced during the adipogenesis of 3T3-L1 cells and human mesenchymal stem cells. Although MLPH did not affect lipid metabolism, such as lipogenesis or lipolysis, adipogenesis was severely impaired by MLPH depletion. We observed that MLPH prevented excess reactive oxygen species (ROS) accumulation and lipid peroxidation during adipogenesis and in mature adipocytes. In addition, increased MLPH expression was observed under cirrhotic conditions in liver cancer cells and its overexpression also reduced ROS and lipid peroxidation. Our findings demonstrate that MLPH is a novel adipogenic factor that maintains redox homeostasis by preventing lipid peroxidation and ROS accumulation, which could lead to metabolic diseases.