Muscle Research Articles

The sodium/ascorbic acid co-transporter SVCT2 distributes in a striated membrane-enriched domain at the M-band level in slow-twitch skeletal muscle fibers.

Vitamin C plays key roles in cellular homeostasis, functioning as a potent antioxidant and a positive regulator of cell differentiation. In skeletal muscle, the vitamin C/sodium co-transporter SVCT2 is preferentially expressed in oxidative slow fibers. SVCT2 is up-regulated during the early fusion of primary myoblasts and decreases during initial myotube growth, indicating the relevance of vitamin C uptake via SVCT2 for early skeletal muscle differentiation and fiber-type definition. However, our understanding of SVCT2 expression and function in adult skeletal muscles is still limited. In this study, we demonstrate that SVCT2 exhibits an intracellular distribution in chicken slow skeletal muscles, following a highly organized striated pattern. A similar distribution was observed in human muscle samples, chicken cultured myotubes, and isolated mouse myofibers. Immunohistochemical analyses, combined with biochemical cell fractionation experiments, reveal a strong co-localization of SVCT2 with intracellular detergent-soluble membrane fractions at the central sarcomeric M-band, where it co-solubilizes with sarcoplasmic reticulum proteins. Remarkably, electrical stimulation of cultured myofibers induces the redistribution of SVCT2 into a vesicular pattern. Our results provide novel insights into the dynamic roles of SVCT2 in different intracellular compartments in response to functional demands.

JAK inhibition with tofacitinib rapidly increases contractile force in human skeletal muscle.

Reduction in muscle contractile force associated with many clinical conditions incurs serious morbidity and increased mortality. Here, we report the first evidence that JAK inhibition impacts contractile force in normal human muscle. Muscle biopsies were taken from patients who were randomized to receive tofacitinib (n = 16) or placebo (n = 17) for 48 h. Single-fiber contractile force and molecular studies were carried out. The contractile force of individual diaphragm myofibers pooled from the tofacitinib group (n = 248 fibers) was significantly higher than those from the placebo group (n = 238 fibers), with a 15.7% greater mean maximum specific force (P = 0.0016). Tofacitinib treatment similarly increased fiber force in the serratus anterior muscle. The increased force was associated with reduced muscle protein oxidation and FoxO-ubiquitination-proteasome signaling, and increased levels of smooth muscle MYLK. Inhibition of MYLK attenuated the tofacitinib-dependent increase in fiber force. These data demonstrate that tofacitinib increases the contractile force of skeletal muscle and offers several underlying mechanisms. Inhibition of the JAK-STAT pathway is thus a potential new therapy for the muscle dysfunction that occurs in many clinical conditions.

Identification of CD141+vasculogenic precursor cells from human bone marrow and their endothelial engagement in the arteriogenesis by co-transplantation with mesenchymal stem cells

BackgroundCritical limb ischemia (CLI) is a condition characterized by insufficient blood flow to the lower limbs, resulting in severe ischemia and potentially leading to amputation. This study aims to identify novel vasculogenic precursor cells (VPCs) in human bone marrow and evaluate their efficacy in combination with bone marrow-derived mesenchymal stem cells (BM-MSCs) for the treatment of CLI.MethodsEx vivo cultured VPCs and BM-MSCs from bone marrow were characterized and their effects on neovascularization and long-term tissue regeneration were tested in a mouse CLI model.ResultsVPCs, expressing high levels of hepatocyte growth factor and c-MET, were identified from human bone marrow aspirates. These cells exhibited strong vasculogenic capacity in vitro but possessed a cellular phenotype distinct from those of previously reported endothelial precursor cells in circulation or cord blood. They also expressed most surface markers of BM-MSCs and demonstrated multipotent differentiation ability. Screening of 376 surface markers revealed that VPCs uniquely display CD141 (thrombomodulin). CD141+VPCs are present in BM aspirates as a rare population and can be expanded ex vivo with a population doubling time of approximately 20 h, generating an elaborate vascular network even under angiogenic factor-deficient conditions and recruiting BM-MSCs to the network as pericyte-like cells. Intramuscular transplantation of a combination of human CD141+VPCs and BM-MSCs at a ratio of 2:1 resulted in limb salvage, blood flow recovery, and regeneration of large vessels in the femoral artery-removed CLI model, with an efficacy superior to that of singular transplantation. Importantly, large arteries and arterioles in dual cell transplantation expressed human CD31 in the intima and human α-smooth muscle actin in media layer at 4 and 12 weeks, likely indicating their lineage commitment to endothelial cells and vascular smooth muscle, respectively, in vivo.ConclusionDual-cell therapy using BM-derived CD141+ VPCs and BM-MSCs holds potential for further development in clinical trials to treat peripheral artery disease and diabetic ulcers.

The 24-hour molecular landscape after exercise in humans reveals MYC is sufficient for muscle growth.

A detailed understanding of molecular responses to a hypertrophic stimulus in skeletal muscle leads to therapeutic advances aimed at promoting muscle mass. To decode the molecular factors regulating skeletal muscle mass, we utilized a 24-h time course of human muscle biopsies after a bout of resistance exercise. Our findings indicate: (1) the DNA methylome response at 30 min corresponds to upregulated genes at 3 h, (2) a burst of translation- and transcription-initiation factor-coding transcripts occurs between 3 and 8 h, (3) changes to global protein-coding gene expression peaks at 8 h, (4) ribosome-related genes dominate the mRNA landscape between 8 and 24 h, (5) methylation-regulated MYC is a highly influential transcription factor throughout recovery. To test whether MYC is sufficient for hypertrophy, we periodically pulse MYC in skeletal muscle over 4 weeks. Transient MYC increases muscle mass and fiber size in the soleus of adult mice. We present a temporally resolved resource for understanding molecular adaptations to resistance exercise in muscle ( http://data.myoanalytics.com ) and suggest that controlled MYC doses influencethe exercise-related hypertrophic transcriptional landscape.

Organ Tropism of Angiostrongylus vasorum Larval Stages in Infected African Giant Snails (Lissachatina fulica)

Angiostrongylus vasorum is a metastrongyloid lungworm causing severe cardiovascular disease in domestic and wild animals. During its heteroxenous life cycle, A. vasorum requires obligate gastropod intermediate hosts. Little is known about A. vasorum larval organ tropism and development in gastropod intermediate hosts. Thus, the aim of this study was to analyze in vivo development of A. vasorum larval stages in experimentally infected African giant snails (Lissachatina fulica). Adult L. fulica (n = 26) were orally infected with A. vasorum-L1 and thereafter continuously euthanized. Gastropod organs were artificially digested and microscopically analyzed for the presence of A. vasorum larvae. Moreover, paraffin-fixed organs were investigated histologically for snail-borne innate immune response. In the current study, the success of L. fulica oral infection was demonstrated, thereby reaching infection rates of up to 49.7%. During snail infection, an organ tropism of A. vasorum larvae was detected for the lungs and the foot muscular tissue. Overall, A. vasorum-driven gastropod innate immune reactions against larvae varied greatly. In some specimens, larvae were found effectively ensnared by recruited hemocytes, resulting in granuloma formation, whilst in others, hemocyte-mediated reactions were barely observed. Nevertheless, these evidences demand more studies on hemocyte-derived effector mechanisms against A. vasorum.

Integrative analysis of gene expression, protein abundance, and metabolomic profiling elucidates complex relationships in chronic hyperglycemia-induced changes in human aortic smooth muscle cells

Type 2 diabetes mellitus (T2DM) is a major public health concern with significant cardiovascular complications (CVD). Despite extensive epidemiological data, the molecular mechanisms relating hyperglycemia to CVD remain incompletely understood. We here investigated the impact of chronic hyperglycemia on human aortic smooth muscle cells (HASMCs) cultured under varying glucose conditions in vitro, mimicking normal (5 mmol/L), pre-diabetic (10 mmol/L), and diabetic (20 mmol/L) conditions, respectively. Normal HASMC cultures served as baseline controls, and patient-derived T2DM-SMCs served as disease controls. Results showed significant increases in cellular proliferation, area, perimeter, and F-actin expression with increasing glucose concentration (p < 0.01), albeit not exceeding the levels in T2DM cells. Atomic force microscopy analysis revealed significant decreases in Young’s moduli, membrane tether forces, membrane tension, and surface adhesion in SMCs at higher glucose levels (p < 0.001), with T2DM-SMCs being the lowest among all the cases (p < 0.001). T2DM-SMCs exhibited elevated levels of selected pro-inflammatory markers (e.g., ILs-6, 8, 23; MCP-1; M-CSF; MMPs-1, 2, 3) compared to glucose-treated SMCs (p < 0.01). Conversely, growth factors (e.g., VEGF-A, PDGF-AA, TGF-β1) were higher in SMCs exposed to high glucose levels but lower in T2DM-SMCs (p < 0.01). Pathway enrichment analysis showed significant increases in the expression of inflammatory cytokine-associated pathways, especially involving IL-10, IL-4 and IL-13 signaling in genes that are up-regulated by elevated glucose levels. Differentially regulated gene analysis showed that compared to SMCs receiving normal glucose, 513 genes were upregulated and 590 genes were downregulated in T2DM-SMCs; fewer genes were differentially expressed in SMCs receiving higher glucose levels. Finally, the altered levels in genes involved in ECM organization, elastic fiber synthesis and formation, laminin interactions, and ECM proteoglycans were identified. Growing literature suggests that phenotypic switching in SMCs lead to arterial wall remodeling (e.g., change in stiffness, calcific deposits formation), with direct implications in the onset of CVD complications. Our results suggest that chronic hyperglycemia is one such factor that leads to morphological, biomechanical, and functional alterations in vascular SMCs, potentially contributing to the pathogenesis of T2DM-associated arterial remodeling. The observed differences in gene expression patterns between in vitro hyperglycemic models and patient-derived T2DM-SMCs highlight the complexity of T2DM pathophysiology and underline the need for further studies.

VRAC Complex Modulates Mechano-Electrical Signal Responses in Human Airway Smooth Muscle Shortening.

Leucine-rich repeat containing 8A (LRRC8A) is an obligatory constituent of the volume-regulated anion channel (VRAC) that is fundamental to a wide range of biological processes, including regulating cell size, proliferation, and migration. Here we explored the physiological role for VRAC in excitation-contraction (E-C) coupling and shortening of human airway smooth muscle (HASM). In HASM cells, pharmacological inhibition of VRAC with DCPIB (0.1-10 μM) markedly attenuated swell-activated Cl- conductance and contractile agonist (histamine or carbachol)-induced cellular stiffening as measured by single-cell patch clamp and optical magnetic twisting cytometry, respectively. In addition, HASM cells treated with DCPIB or transfected with LRRC8A-targeting siRNA showed reduced agonist-induced phosphorylation of protein kinase B (AKT), paxillin, myosin phosphatase target subunit 1 (MYPT1), and myosin light chain (MLC). Consistent with the changes of these E-C coupling effectors, DCPIB appreciably decreased agonist-induced small airways narrowing in human precision-cut lung slices (hPCLS). Taken together, our findings shed a new light on the mechanistic link between HASM shortening and regulatory volume decrease via LRRC8A, revealing a previously unrecognized nodal point for modulation of the E-C coupling and acute airways constriction.

The novel role of complement 3 in Wnt5a-mediated vascular smooth muscle cell calcification

Abstract Background Although vascular calcification (VC) is a risk factor for cardiovascular and all-cause mortality, a therapy is not yet available. VC involves the transdifferentiation of vascular smooth muscle cells (VSMC) towards an osteochondrogenic lineage that results in calcium phosphate salts deposition in the arterial wall. We have previously shown an association between plasma WNT5A levels and new onset and progression of coronary artery calcification. Purpose We aimed to study the poorly understood role of Wnt5a in VSMC calcification. Methods Study 1 included 18 patients with coronary artery disease (CAD) undergoing cardiac surgery; VSMC were isolated from their saphenous veins to perform in vitro assays and microarrays. Study 2 included 11 patients with CAD; IMA were treated ex vivo with Wnt5a recombinant protein (rWnt5a) to perform western blot (WB) analyses. Study 3 included 647 patients with CAD; RNA sequencing was performed on samples from their internal mammary arteries (IMA), IMA perivascular adipose (PVAT), and thoracic adipose tissue (ThAT). VSMC and human aortic smooth muscle cells (HASMC) from healthy donors were grown in osteogenic medium in the presence or absence of rWnt5a with or without specific protein inhibitors. Calcium deposition and expression of VC markers (i.e. RUNX2, BMP2, and MSX2) were assessed with a colorimetric assay and by RT-qPCR, respectively. Phosphorylation/activation of non-canonical Wnt pathway effectors was evaluated by WB analyses. Results rWnt5a treatment significantly increased calcium deposition in both VSMC and HASMC at a concentration that activates both JNK and CaMKII, that are effectors of the non-canonical planar cell polarity pathway and the calcium-dependent pathway, respectively. Inhibition of either JNK or CaMKII could not counteract rWnt5a-mediated increase in VSMC calcium deposition; whereas, inhibition of both non-canonical pathway effectors (JNK-i and CaMKII-i) prevented rWnt5a-mediated increase in calcium deposition by VSMC (A) and HASMC. Inhibition of JNK and CaMKII also prevented rWnt5a-induced gene expression of VC markers, such as RUNX2 (B). rWnt5a treatment in IMA increased the activation of JNK and CaMKII. Patients with higher WNT5A levels in IMA had significantly higher RUNX2 levels. By intersecting RNA sequencing and microarray data complement 3 (C3) resulted as the most upregulated gene in rWnt5a-treated VSMC among those genes whose levels positively correlated in IMA with both WNT5A and RUNX2 expression (C). Patients with higher WNT5A levels in IMA, their PVAT, and ThAT had significantly higher C3 levels (D), and patients with higher levels of C3AR1, that is the gene coding for the C3a receptor, had higher VC markers expression. C3 inhibition (C3-i) with a C3AR1 antagonist counteracted Wnt5a-induced VSMC calcium deposition (E). Conclusions Non-canonical Wnt signalling promotes VSMC calcification through C3. Wnt5a may be a therapeutic target in VC.Abstract Figure

Suppression of Fibulin 5 Attenuated Pulmonary Arterial Hypertension Associated with Congenital Heart Disease via Mitigating Pulmonary Arterial Smooth Muscle Cell Dysfunction

Abstract Backgrounds: The specific molecular pathogenesis of pulmonary arterial hypertension associated with congenital heart disease (CHD-PAH) and the reversal still remain elusive. Fibulin 5 was involved in the regulation of cardiovascular system while little is known about the expression and functions of fibulin 5 in the development of CHD-PAH. This study aimed to investigate the role of fibulin 5 in the pathogenesis of the disease. Methods Lung samples were obtained both from patients with CHD-PAH and aortocaval shunt-associated PAH rat models. TGF-β1was used to induce human pulmonary artery smooth muscle cells (hPASMCs) dysfunction and lentiviruses were responsible for alteration of fibulin 5 expression. In an effort to explore the specific role of fibulin 5, an inhibitor of phosphatidylinositol-3-kinases (PI3K) /protein-serine-threonine kinase (AKT) which was defined as the TGF-β1-related downstream signaling was applied for further exploration. Results Fibulin 5 was pronouncedly elevated in the PASMCs of the remodeled pulmonary arterioles from patients with CHD-PAH and shunt-associated PAH rats. We found that over-expression of fibulin 5 could promote hPASMCs dysfunction induced by TGF-β1 and it could be reversed by the PI3K/AKT inhibitor LY294002 suggesting the essential role of TGF-β1/PI3K/AKT signaling activation in phenotypic switch, proliferation and migration of PASMCs. Moreover, an adeno-associated virus vector encoding fibulin 5 by intratracheally instillation with rats improve the hemodynamic parameters in shunt-associated PAH rats and its related pulmonary artery remodeling. Conclusion Over-expression of fibulin 5 could significantly promote hPASMCs dysfunction and pulmonary artery remodeling via reinforcing TGF-β1/PI3K/AKT signaling activation, which highlighted the potential valuable pharmacological target for the treatment of CHD-PAH.Fibulin 5 was over-expressed in PAHInhibition of fibulin 5 attenuated PAH

Metabolic alterations in human pulmonary artery smooth muscle cells treated with PDGF-BB.

Metabolic abnormalities are considered to play a key regulatory role in vascular remodeling of pulmonary arterial hypertension. However, to date, there is a paucity of research documenting the changes in metabolome profiles within the supernatants of pulmonary artery smooth muscle cells (PASMC) during their transition from a contractile to a synthetic phenotype. CCK-8 and Edu staining assays were used to evaluate the cell viability and proliferation of human PASMCs. IncuCyte ZOOM imaging system was used to continuously and automatically detect the migration of the PASMCs. A targeted metabolomics profiling was performed to quantitatively analyze 121 metabolites in the supernatant. Orthogonal partial least squares discriminant analysis was used to discriminate between PDGF-BB-induced PASMCs and controls. Metabolite set enrichment analysis was adapted to exploit the most disturbed metabolic pathways. Human PASMCs exhibited a transformation from contractile phenotype to synthetic phenotype after PDGF-BB induction, along with a significant increase in cell viability, proliferation, and migration. Metabolites in the supernatants of PASMCs treated with or without PDGF-BB were well profiled. Eleven metabolites were found to be significantly upregulated, whereas seven metabolites were downregulated in the supernatants of PASMCs induced by PDGF-BB compared to the vehicle-treated cells. Fourteen pathways were involved, and pyruvate metabolism pathway was ranked first with the highest enrichment impact followed by glycolysis/gluconeogenesis and pyrimidine metabolism. Significant and extensive metabolic abnormalities occurred during the phenotypic transformation of PASMCs. Disturbance of pyruvate metabolism pathway might contribute to pulmonary vascular remodeling.

Parathyroid hormone exacerbates pulmonary hypertension via parathyroid hormone receptors on pulmonary artery smooth muscle cells

Abstract Background Pulmonary hypertension (PH) is a right heart failure disease and can be fatal. Parathyroid hormone (PTH) is a bone metabolism hormone and regulates calcium and phosphorus homeostasis. Previous studies have suggested that PTH affects the cardiovascular system and influences cardiovascular diseases. We hypothesized that PTH may play a role in the pathogenesis of PH. Purpose This study aimed to investigate whether PTH has a critical role in pulmonary hemodynamics. Method Serum PTH levels were measured in patients with PH or suspected PH undergoing right heart catheterization. We tested whether the regulation of PTH and the PTH receptor (PTH1R) affected PH in hypoxia (Hx)-induced PH model mice and Sugen/hypoxia (SuHx)-induced PH model ras. Hx mice were treated with PTH daily for 3 weeks or with an inhaled AAV-shRNA system to knockdown PTH1R expression in the lung. SuHx rats underwent parathyroidectomy (PTx). We measured physical data and right ventricular systolic pressure (RVSP) in these models. Human pulmonary artery smooth muscle cells (PASMCs) were cultured and treated with PTH to examine the direct effects of PTH. Result In the clinical study, we enrolled 30 participants and found serum PTH levels correlated with mean pulmonary artery pressure (r = 0.67) and pulmonary vascular resistance (r = 0.62). The ROC curve showed a cut-off PTH level of 46.0 pg/mL (68.2% sensitivity, 100% specificity) to predict PH. In animal models, PTH treatment exacerbated right ventricular hypertrophy and increased right ventricular systolic pressure (RVSP) in Hx mice compared with non-treated Hx mice (Figure 1). In contrast, knockdown of PTH1R in the lungs improved PH in Hx mice, and PTx significantly suppressed PH in SuHx rats (Figure 2). PTH promoted migration and proliferation through PTH receptor-ERK signaling in PASMCs. Conclusion Our clinical and experimental data showed that PTH exacerbates PH and suggest that PTH/PTH1R signaling would be a new target for PH treatment.

Kiss1 receptor knockout exacerbates airway hyperresponsiveness and remodeling in a mouse model of allergic asthma

BackgroundIn asthma, sex-steroids signaling is recognized as a critical regulator of disease pathophysiology. However, the paradoxical role of sex-steroids, especially estrogen, suggests that an upstream mechanism or even independent of estrogen plays an important role in regulating asthma pathophysiology. In this context, in our previous studies, we explored kisspeptin (Kp) and its receptor Kiss1R’s signaling in regulating human airway smooth muscle cell remodeling in vitro and airway hyperresponsiveness (AHR) in vivo in a mouse (wild-type, WT) model of asthma. In this study, we evaluated the effect of endogenous Kp in regulating AHR and remodeling using Kiss1R knockout (Kiss1R−/−) mice.MethodsC57BL/6J WT (Kiss1R+/+) and Kiss1R−/− mice, both male and female, were intranasally challenged with mixed-allergen (MA) and/or phosphate-buffered saline (PBS). We used flexiVent analysis to assess airway resistance (Rrs), elastance (Ers), and compliance (Crs). Following this, broncho-alveolar lavage (BAL) was performed for differential leukocyte count (DLC) and cytokine analysis. Histology staining was performed using hematoxylin and eosin (H&E) for morphological analysis and Masson’s Trichrome (MT) for collagen deposition. Additionally, lung sections were processed for immunofluorescence (IF) of Ki-67, α-smooth muscle actin (α-SMA), and tenascin-c.ResultsInterestingly, the loss of Kiss1R exacerbated lung function and airway contractility in mice challenged with MA, with more profound effects in Kiss1R−/− female mice. MA-challenged Kiss1R−/− mice showed a significant increase in immune cell infiltration and proinflammatory cytokine levels. Importantly, the loss of Kiss1R aggravated Th2/Th17 biased cytokines in MA-challenged mice. Furthermore, histology of lung sections from Kiss1R−/− mice showed increased collagen deposition on airway walls and mucin production in airway cells compared to Kiss1R+/+ mice. In addition, immunofluorescence analysis showed loss of Kiss1R significantly aggravated airway remodeling and subsequently AHR.ConclusionsThese findings demonstrate the importance of inherent Kiss1R signaling in regulating airway inflammation, AHR, and remodeling in the pathophysiology of asthma.

Identification of peripheral nerve functional fascicles in Sprague-Dawley rats by the carbon quantum dot-Annexin V antibody complex

To explore a method to identify the sensory and motor fascicles of the peripheral nerve to achieve accurate peripheral nerve functional fascicle suture. The peripheral nerve Sunderland V injury model, muscle branch of the femoral nerve and saphenous nerve were established in the bilateral femoral nerves of Sprague-Dawley (SD) rats. The specific samples were grouped as follows: the main trunk of the femoral nerve was exposed bilaterally and cut with microscopic scissors in the main trunk of the femoral nerve to prepare a model of Sunderland V injury in the mixed fascicle of peripheral nerves; the muscle branch of the femoral nerve was exposed bilaterally and cut in the middle section of the muscle branch of the femoral nerve to prepare a model of Sunderland V injury in the motor fascicle of peripheral nerves; the saphenous nerve was exposed bilaterally and cut at 1 cm below the patella to prepare a model of Sunderland V injury to the sensory fascicle of the peripheral nerves. A carbon quantum dot (CD)-annexin V antibody complex was prepared and applied to the distal and proximal nerve stumps of the peripheral nerve Sunderland V injury model groups of SD rats. Under the excitation light source of a 380 nm uv lamp, fluorescence color development was observed under a fluorescence microscope after 5, 10, 15, and 20 min. At 5 min, sections of the bilateral femoral nerve trunk, muscular branches of the femoral nerve, and Sunderland V lesion of the saphenous nerve in SD rats were only dark in color under the microscope, and there was no difference in fluorescence. The intensity of the staining increased significantly for 10–20 min. The sensory fascicles and saphenous nerves of the femoral nerve trunk showed blue fluorescence under the CD-Annexin V antibody complex staining, while the motor fascicles and muscle branches of the femoral nerve trunk showed no fluorescence. Fluorescence intensity gradually decreased after 20 min of staining. There was no significant difference in the staining intensity at 5, 10, 15, and 20 min in each group. Our results suggest that the CD-Annexin antibody complex can be used to identify functional fascicles of peripheral nerves in SD rats.

In-vitro and in-vivo assessment of the bactericidal potential of peracetic acid and hydrogen peroxide disinfectants against A. hydrophila infection in Nile tilapia and their effect on water quality indices and fish stress biomarkers

This study aimed to assess the in vitro and in vivo disinfectant potential of peracetic acid (PAA) (1 mg/L) and hydrogen peroxide (H2O2) (20 mg/L) on the physicochemical and microbiological water quality parameters of fish aquaria, the microbial density of Nile tilapia muscular tissue, fish hepatic cortisol levels, and antioxidant biomarkers. In vitro, PAA and H2O2 reduced A. hydrophila colony viability by 5 log units after 30 and 5 min of contact time, respectively. PAA and H2O2 were added to aquaria water twice a week for the three-week experiment. Increased fish escape reflexes were observed only in the PAA group, which returned to normal within 10 min. No mortalities were reported in either the PAA or H2O2 groups. An in vivo experimental challenge with a pathogenic strain of A. hydrophila revealed a 20% reduction in mortality in the PAA group, with no mortalities in the H2O2 group. Cortisol levels and antioxidant markers were measured to assess the impact of PAA and H2O2 on fish health. Cortisol levels in the PAA and H2O2 groups were significantly higher than in the control group after disinfectant exposure, but they progressively returned to normal. A significant reduction in superoxide dismutase (SOD) and catalase (CAT) activity, along with considerably higher glutathione peroxidase (GPx) and malondialdehyde (MDA) enzymatic activity, was observed in the PAA and H2O2 groups compared to the control group. A substantial increase in total antioxidant capacity (TAC) was recorded in the PAA group. Physicochemical analyses revealed reduced pH and increased dissolved oxygen levels in the PAA and H2O2 groups. Microbiological analyses showed a significant reduction in bacterial density in water by 64% and 76% after 30 min of exposure to PAA and H2O2, respectively, with a non-significant increase in microbial count after bacterial challenge. Additionally, aerobic bacterial count, Aeromonas spp., and psychotropic bacterial count in fish muscle showed a significant reduction in the H2O2 group compared to the PAA and control groups before and after infection. The study concludes that regular application of PAA and H2O2 can temporarily reduce bacterial load in aquaria and fish muscle, regulate stress responses, and improve fish health by reducing A. hydrophila-induced infections and improving survival.

Transcriptome and targeted metabolome analysis of lipid profiles, nutrients compositions and volatile compounds in longissimus dorsi of different pig breeds.

Improving meat quality is important for commercial production and breeding. The molecular mechanism of intramuscular fat (IMF) deposition and meat characteristics remain further study. This study aimed to study the mechanism of IMF deposition and meat characteristics including redox potential, nutrients compositions and volatile compounds in longissimus dorsi (LD) by comparing with different pig breeds including Shanghai white (SW), Duroc x (Landrace Yorkshire) (DLY) and Laiwu (LW) pigs. Results showed that the contents of IMF, triglyceride (TG), total cholesterol (TC), and redox potential parameters were lower, while the content of MDA and activity of lactate dehydrogenase (LDH) were higher in LD of SW pigs compared with LW pigs (p<0.05). No differences were observed about these parameters between SW and DLY pigs. Also, the contents of medium-long chain fatty acids and γ-aminobutyric acid (GABA) were higher, while Asp was lower in LD of SW pigs compared with LW pigs (p<0.05). Volatile compounds results showed that 6 ketones, 4 alkenes, 11 alkanes, 2 aldehydes, 1 alcohol were increased and cholesterol was decreased in SW pigs compared with LW pigs. Transcriptome results showed that differential expressed genes involved in lipid synthesis, metabolism and transport in LD between SW and LW pigs, which were further verified by qPCR. Spearman correlation showed that HSL and Nedd4 were positively related to contents of TG and IMF, while negatively related to volatile compounds and fatty acids (p<0.05). Plin3 and Mgll were negatively related to contents of TG, IMF and cholesterol, while positively related to MDA, LDH, and volatile compounds (p<0.05). PPARA was negatively related to contents of TC and IMF, and activity of SOD, while positively related to volatile compounds (p<0.05). Our study provided new insights into potential mechanisms of IMF deposition, nutrients composition and volatile compounds of muscular tissues of different pig breeds.

Compliant Grasp Control Method for the Underactuated Prosthetic Hand Based on the Estimation of Grasping Force and Muscle Stiffness with sEMG

Human muscles can generate force and stiffness during contraction. When in contact with objects, human hands can achieve compliant grasping by adjusting the grasping force and the muscle stiffness based on the object’s characteristics. To realize humanoid-compliant grasping, most prosthetic hands obtain the stiffness parameter of the compliant controller according to the environmental stiffness, which may be inconsistent with the amputee’s intention. To address this issue, this paper proposes a compliant grasp control method for an underactuated prosthetic hand that can directly obtain the control signals for compliant grasping from surface electromyography (sEMG) signals. First, an estimation method of the grasping force is established based on the Huxley muscle model. Then, muscle stiffness is estimated based on the muscle contraction principle. Subsequently, a relationship between the muscle stiffness of the human hand and the stiffness parameters of the prosthetic hand controller is established based on fuzzy logic to realize compliant grasp control for the underactuated prosthetic hand. Experimental results indicate that the prosthetic hand can adjust the desired force and stiffness parameters of the impedance controller based on sEMG, achieving a quick and stable grasp as well as a slow and gentle grasp on different objects.

Muscle‐Inspired Robust Anisotropic Cellulose Conductive Hydrogel for Multidirectional Strain Sensors and Implantable Bioelectronics

AbstractIntegrating superior mechanical performance, anisotropic conductivity, and biocompatibility into conductive hydrogels as all‐in‐one human‐machine interaction device remains challenging. Herein, by mimicking the anisotropic structures of human muscles, a robust anisotropic conductive hydrogel is developed by initially aligning polyvinyl alcohol with polypyrrole decorated cellulose nanofibrils to form an anisotropically oriented polymer networks, followed by post‐crosslinking with tannic acid (TA). Introducing TA into hydrogel network permanently secures its hierarchically anisotropic structure through multiple hydrogen bonds, thus endowing the hydrogel with exceptional mechanical properties (tensile strength of 11.41 MPa, toughness of 12.44 MJ m−3), anisotropic adhesive property, and direction‐dependent conductivity. With these attributes, a hydrogel strain sensor with excellent multidirectional sensitivity is developed, enabling stable monitoring of multi‐degrees of freedom joint movements in the human body and facilitating the control of a multiaxial virtual robot manipulator. Moreover, the in vitro/vivo tests demonstrate exceptional biocompatibility and anti‐biofouling properties of the as‐prepared hydrogel sensor, maintaining stable electronic response signals for over 14 days after successful implantation into the Achilles tendon of mice. Overall, this study presents a promising approach for designing conductive hydrogels with superior mechanical properties and anisotropic functionality for emerging applications in both in vitro and in vivo human‐machine interface materials.

Thermostable bFGF Improves Cell Lifespan by Enhancing Cell Activity in the Long-Term Culture of Human Orbicularis Oculi Stem Cells.

Stem cells derived from human orbicularis oculi muscle (hOOM) are a valuable resource for cell therapy. However, when stem cells are continuously cultured, their abilities tend to deteriorate over time. One method to address this issue is to use basic fibroblast growth factor (bFGF) to maintain the stem cell functionality. The limitation is that bFGF is unstable under mammalian cell culture conditions with a half-life of only 8 hours, which poses a significant challenge to the production and maintenance of high-quality stem cells. In this study, we used thermostable bFGF (TS-bFGF) and demonstrated that hOOM-derived stem cells cultured with TS-bFGF exhibited superior proliferation, stem cell function, reduced reactive oxygen species, and cellular senescence delay effect compared to cells cultured with wild-type bFGF. Considering the pivotal role of stem cells in broad ranges of applications such as regenerative medicine and cultured meat, we anticipate that TS-bFGF, owing to its thermostability and long-lasting properties, will contribute significantly to the acquisition of high-quality stem cells.

Novel Bioreactor Design for Non-invasive Longitudinal Monitoring of Tissue-Engineered Heart Valves in 7T MRI and Ultrasound.

The development of cardiovascular implants is abundant, yet their clinical adoption remains a significant challenge in the treatment of valvular diseases. Tissue-engineered heart valves (TEHV) have emerged as a promising solution due to their remodeling capabilities, which have been extensively studied in recent years. However, ensuring reproducible production and clinical translation of TEHV requires robust longitudinal monitoring methods.Cardiovascular magnetic resonance imaging (MRI) is a non-invasive, radiation-free technique providing detailed valvular imaging and functional assessment. To facilitate this, we designed a state-of-the-art metal-free bioreactor enabling dynamic MRI and ultrasound imaging. Our compact bioreactor, tailored to fit a 72mm bore 7T MRI coil, features an integrated backflow design ensuring MRI compatibility. A pneumatic drive system operates the bioreactor, minimizing potential MRI interference. The bioreactor was digitally designed and constructed using polymethyl methacrylate, utilizing only polyether ether ketone screws for secure fastening. Our biohybrid TEHV incorporates a non-degradable polyethylene terephthalate textile scaffold with fibrin matrix hydrogel and human arterial smooth muscle cells.As a result, the bioreactor was successfully proven to be MRI compatible, with no blooming artifacts detected. The dynamic movement of the TEHVs was observed using gated MRI motion artifact compensation and ultrasound imaging techniques. In addition, the conditioning of TEHVs in the bioreactor enhanced ECM production. Immunohistology demonstrated abundant collagen, α-smooth muscle actin, and a monolayer of endothelial cells throughout the valve cusp. Our innovative methodology provides a physiologically relevant environment for TEHV conditioning and development, enabling accurate monitoring and assessment of functionality, thus accelerating clinical acceptance.

Activation of nuclear receptor pregnane-X-receptor protects against abdominal aortic aneurysm by inhibiting oxidative stress

Abdominal aortic aneurysm (AAA) is a life-threatening condition, but effective medications to prevent its progression and rupture are currently lacking. The nuclear receptor pregnane-X-receptor (PXR) plays a crucial role in vascular homeostasis. However, the role of PXR in AAA development remains unknown. We first detected the PXR expression in human and murine AAA tissues by RT-qPCR and Western blot. To investigate the potential role of PXR in the development of AAA, we used adeno-associated virus-mediated overexpression of PXR and pharmacological activation of PXR by ginkgolide A (GA) in mouse AAA models induced by both angiotensin II (AngII) and calcium phosphate [Ca3(PO4)2]. The underlying mechanism was further explored using RNA-sequencing and molecular biological analyses. We found a significant decrease in both mRNA and protein levels of PXR in both human and murine aortic smooth muscle cells from AAA tissues, accompanied with phenotypic switching of vascular smooth muscle cell and increased oxidative stress. PXR overexpression in abdominal aortas and GA treatment successfully suppressed AAA formation in both mouse AAA models. RNA-sequencing data revealed that PXR activation inhibited gamma-aminobutyric acid type A receptor subunit alpha3 (GABRA3) expression. Additional mechanistic studies identified that PXR suppressed AAA through mitigating GABRA3-induced reactive oxygen species (ROS) generation and subsequent phosphorylation of c-Jun N-terminal kinase (JNK). Interestingly, p-JNK was found to induce ubiquitin-proteasome degradation of PXR. In summary, our data unveiled, for the first time, the protective role of PXR against AAA pathogenesis by inhibiting oxidative stress. These findings suggested PXR as a promising therapeutic target for AAA.