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476 results on '"Skeletal Muscle Tissue"'

1. Three-Dimensional Microfibrous Scaffold with Aligned Topography Produced via a Combination of Melt-Extrusion Additive Manufacturing and Porogen Leaching for In Vitro Skeletal Muscle Modeling.

Author

Spedicati, Mattia, Zoso, Alice, Mortati, Leonardo, Chiono, Valeria, Marcello, Elena, and Carmagnola, Irene

Subjects
*SKELETAL muscle, *POLYCAPROLACTONE, *LEACHING, *POLYMER blends, *CELL culture, *TOPOGRAPHY, *POLYMER clay
Abstract

Skeletal muscle tissue (SMT) has a highly hierarchical and anisotropic morphology, featuring aligned and parallel structures at multiple levels. Various factors, including trauma and disease conditions, can compromise the functionality of skeletal muscle. The in vitro modeling of SMT represents a useful tool for testing novel drugs and therapies. The successful replication of SMT native morphology demands scaffolds with an aligned anisotropic 3D architecture. In this work, a 3D PCL fibrous scaffold with aligned morphology was developed through the synergistic combination of Melt-Extrusion Additive Manufacturing (MEAM) and porogen leaching, utilizing PCL as the bulk material and PEG as the porogen. PCL/PEG blends with different polymer ratios (60/40, 50/50, 40/60) were produced and characterized through a DSC analysis. The MEAM process parameters and porogen leaching in bi-distilled water allowed for the development of a micrometric anisotropic fibrous structure with fiber diameters ranging from 10 to 100 µm, depending on PCL/PEG blend ratios. The fibrous scaffolds were coated with Gelatin type A to achieve a biomimetic coating for an in vitro cell culture and mechanically characterized via AFM. The 40/60 PCL/PEG scaffolds yielded the most homogeneous and smallest fibers and the greatest physiological stiffness. In vitro cell culture studies were performed by seeding C2C12 cells onto a selected scaffold, enabling their attachment, alignment, and myotube formation along the PCL fibers during a 14-day culture period. The resultant anisotropic scaffold morphology promoted SMT-like cell conformation, establishing a versatile platform for developing in vitro models of tissues with anisotropic morphology. [ABSTRACT FROM AUTHOR]

Published
2024
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2. Restoring rats’ endurance ability after forced physical exercise under various methods of allogeneic biomaterial implantation

Author

Lebedeva Anna, Musina Lyalya, Galautdinov Mars, Prusakov Alexey, Yashin Anatoly, and Ponamarev Vladimir

Subjects
allogeneic biomaterial, skeletal muscle tissue, fibrosis inhibition, actoprotection, Veterinary medicine, SF600-1100
Abstract

One of the manifestations of skeletal muscle plasticity is its atrophy, as an adaptive response to catabolic stimuli. They can occur during forced exhausting physical activity. Injection of local anesthetics, glucocorticosteroids, etc., is widely used to correct such pathological manifestations. The purpose of the study was to reveal the skeletal muscle morphofunctional characteristics of experimental animals after forced physical activity under conditions of subcutaneous and combined methods of administration of allogeneic biomaterial (BMA). The model of anaerobic physical exercise was forced swimming of male rats with a load of 10% of body weight. After the swimming test, the animals were divided into four groups. In the first (experimental) group (n=10), the BMA suspension was administered only subcutaneously. In the second (experimental) group (n=10), BMA suspension was injected in combination, i.e., into the muscles of the limbs and subcutaneously. In the control groups, saline solution was administered using similar methods. After tissue collection on days 5 and 21, morphological, physiological, and statistical studies were carried out. The use of BMA contributed to an increase in load tolerance, and accelerated restoration of muscle tissue, hypertrophy, and hyperplasia. There was a decrease in inflammation, and restoration of microcirculation and ultrastructure of muscle fibers: contractile elements, energy balance of cells, and proliferative activation of the nuclear apparatus. Implantation of BMA promoted inhibition of fibrosis, reduction in the number of necrotic muscle fibers, and chemoattraction of macrophages. The greatest effectiveness determined was with the combined administration of the biomaterial. BMA has an actoprotective effect.

Published
2024
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4. Effect of Infrared and Green Photomodulation Exposure on the Number of Active Myosatellite Cells in Regenerating Muscles.

Author

Tahaviev, R. V., Golovneva, E. S., and Bryukhin, G. V.

Subjects
*GREEN light, *MUSCLE cells, *CELL nuclei, *LABORATORY rats, *LASERS, *INFRARED lasers, *FEMTOSECOND lasers
Abstract

Reparative properties of infrared laser exposure are well known, but the effects of green laser light are little studied. We analyzed the effects of short (60 sec) and longer (180 sec) exposure to infrared (980 nm) and green (520 nm) laser on the number of activated myosatellite cells in the regenerating m. gastrocnemius of Wistar rats after infliction of an incision wound. Histological preparations were used for morphometric evaluation of myosatellite cells with MyoD+ nuclei. Increased numbers of MyoD+ nuclei were observed on days 3 and 7 after 60-sec exposure to infrared and green laser. [ABSTRACT FROM AUTHOR]

Published
2024
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5. Three-Dimensional Microfibrous Scaffold with Aligned Topography Produced via a Combination of Melt-Extrusion Additive Manufacturing and Porogen Leaching for In Vitro Skeletal Muscle Modeling

Author

Mattia Spedicati, Alice Zoso, Leonardo Mortati, Valeria Chiono, Elena Marcello, and Irene Carmagnola

Subjects
Melt-Extrusion Additive Manufacturing, PCL, PEG, porogen leaching, fibrous scaffold, skeletal muscle tissue, Technology, Biology (General), QH301-705.5
Abstract

Skeletal muscle tissue (SMT) has a highly hierarchical and anisotropic morphology, featuring aligned and parallel structures at multiple levels. Various factors, including trauma and disease conditions, can compromise the functionality of skeletal muscle. The in vitro modeling of SMT represents a useful tool for testing novel drugs and therapies. The successful replication of SMT native morphology demands scaffolds with an aligned anisotropic 3D architecture. In this work, a 3D PCL fibrous scaffold with aligned morphology was developed through the synergistic combination of Melt-Extrusion Additive Manufacturing (MEAM) and porogen leaching, utilizing PCL as the bulk material and PEG as the porogen. PCL/PEG blends with different polymer ratios (60/40, 50/50, 40/60) were produced and characterized through a DSC analysis. The MEAM process parameters and porogen leaching in bi-distilled water allowed for the development of a micrometric anisotropic fibrous structure with fiber diameters ranging from 10 to 100 µm, depending on PCL/PEG blend ratios. The fibrous scaffolds were coated with Gelatin type A to achieve a biomimetic coating for an in vitro cell culture and mechanically characterized via AFM. The 40/60 PCL/PEG scaffolds yielded the most homogeneous and smallest fibers and the greatest physiological stiffness. In vitro cell culture studies were performed by seeding C2C12 cells onto a selected scaffold, enabling their attachment, alignment, and myotube formation along the PCL fibers during a 14-day culture period. The resultant anisotropic scaffold morphology promoted SMT-like cell conformation, establishing a versatile platform for developing in vitro models of tissues with anisotropic morphology.

Published
2024
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6. Imaging-based assessment of body composition in patients with Crohn's disease: a systematic review.

Author

Tang, Wuli, Xie, Gang, Wang, Danni, Li, Ting, Ren, Yitao, Li, Junlin, Deng, Jiaxing, and Li, Kang

Subjects
*CROHN'S disease, *BODY composition, *DUAL-energy X-ray absorptiometry, *MAGNETIC resonance imaging, *MUSCLE mass, *ADIPOSE tissue diseases
Abstract

Background and aims: Body composition changes in patients with Crohn's disease (CD) have received increasing attention in recent years. This review aims to describe the changes in body composition in patients with CD on imaging and to analyze and summarize the prognostic value of body composition. Methods: We systematically searched Web of Science, PubMed, Embase, Cochrane Library, and Medline via OVID for literature published before November 2022, and two researchers independently evaluated the quality of the retrieved literature. Results: A total of 39 publications (32 cohort studies and 7 cross-sectional studies) involving 4219 patients with CD were retrieved. Imaging methods for body composition assessment, including dual-energy X-ray absorptiometry (DXA), computed tomography (CT) and magnetic resonance imaging (MRI), were included in this review. The study found that patients with CD typically have more visceral adipose tissue and less skeletal muscle mass, and the prevalence of sarcopenia and visceral obesity was significantly different in different studies (sarcopenia: 16–100%; visceral obesity: 5.3–30.5%). Available studies suggest that changes in the body composition of CD patients are significantly related to inflammatory status, disease behavior, poor outcomes, and drug efficacy. Conclusion: Altered body composition can be a significant predictor of poor outcomes for CD patients. Therefore, the body composition of CD patients may serve as a potential therapeutic target to help optimize disease management strategies in clinical practice. [ABSTRACT FROM AUTHOR]

Published
2023
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7. Ultrastructure of Myofascial Trigger Points of Skeletal Muscles of Rats after Photobiostimulation with Low-Intensity Red Light.

Author

Bavrina, A. P., Shchelchkova, N. A., Vasyagina, T. I., Pchelin, P. V., Lapshin, R. D., Belousova, I. I., and Nefedova, D. A.

Abstract

The effectiveness of low-intensity red light on myofascial trigger points in skeletal muscle of mature rats was evaluated by electron microscopy and high-resolution respirometry. The revealed changes in mitochondrial ultrastructure and activity of the respiratory chain enzymes indicate the development of hypoxia in the simulation area. Under the influence of low-intensity red light on myofascial trigger points, a decrease in the number of destructively altered muscle fibers and stimulation of mitochondrial respiration were found. These findings indicate intracellular regeneration and the stimulating effect of low-intensity red light on plastic processes. [ABSTRACT FROM AUTHOR]

Published
2023
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8. Improved Performance of Biohybrid Muscle‐Based Bio‐Bots Doped with Piezoelectric Boron Nitride Nanotubes.

Author

Mestre, Rafael, Fuentes, Judith, Lefaix, Laura, Wang, Jiaojiao, Guix, Maria, Murillo, Gonzalo, Bashir, Rashid, and Sánchez, Samuel

Subjects
*BORON nitride, *NANOTUBES, *CELL differentiation, *SKELETAL muscle, *GOLD nanoparticles, *MUSCLES
Abstract

Biohybrid robots, or bio‐bots, integrate living and synthetic materials following a synergistic strategy to acquire some of the unique properties of biological organisms, like adaptability or bio‐sensing, which are difficult to obtain exclusively using artificial materials. Skeletal muscle is one of the preferred candidates to power bio‐bots, enabling a wide variety of movements from walking to swimming. Conductive nanocomposites, like gold nanoparticles or graphene, can provide benefits to muscle cells by improving the scaffolds' mechanical and conductive properties. Here, boron nitride nanotubes (BNNTs), with piezoelectric properties, are integrated in muscle‐based bio‐bots and an improvement in their force output and motion speed is demonstrated. A full characterization of the BNNTs is provided, and their piezoelectric behavior with piezometer and dynamometer measurements is confirmed. It is hypothesized that the improved performance is a result of an electric field generated by the nanocomposites due to stresses produced by the cells during differentiation. This hypothesis is backed with finite element simulations supporting that this stress can generate a non‐zero electric field within the matrix. With this work, it is shown that the integration of nanocomposite into muscle‐based bio‐bots can improve their performance, paving the way toward stronger and faster bio‐hybrid robots. [ABSTRACT FROM AUTHOR]

Published
2023
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9. Informatics-enhanced prediction of failure strength in skeletal muscle tissue.

Author

Tang, Jiabao, Liu, Wenyang, Mao, Yiqi, and Hou, Shujuan

Subjects
*ARTIFICIAL neural networks, *MUSCLE strength, *BAYESIAN field theory, *DATA science, *BIOMATERIALS
Abstract

• A modeling approach enabling an effective integration of data science and informatics tools is proposed. • Bayesian calibration combined with parameter space compression improves model simplicity and effectivity. • The histological parameter is introduced into the model using two in-series artificial neural networks. • Extensive experimental data are used to validate the effectiveness of the proposed approach. Skeletal muscles are susceptible to injury during daily activities and competitive sports. Reliable prediction of tissue failure strength is a major challenge due to the large uncertainty in the mechanical behavior of skeletal muscle tissue. The present study reveals a strong correlation between histological characteristics and skeletal muscle failure strength by means of mechanical and histological experiments. We propose a data-driven hybrid modeling approach that enables an effective integration of data science and informatics tools to capture tissue failure strength. Uncertainty in the tissue failure strength is propagated into the posterior information of reduced model parameters via the Bayesian inference framework and parameter space compression. A histological enhancement to the softening hyperelasticity model is made by linking a quantified tissue-scale histological characteristic and stiff model parameters using artificial neural networks. The model is applied to skeletal muscle tissue from different species and sites to assess its predictive capabilities for physiological differences. The results show that the approach can achieve reliable predictions of skeletal muscle tissue failure strength. The proposed approach can be extended to different scales to enrich the understanding of structure–property linkages for biomaterials. [ABSTRACT FROM AUTHOR]

Published
2024
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11. A Micromanipulation-Actuated Large-Scale Screening to Identify Optimized Microphysiological Model Parameters in Skeletal Muscle Regeneration.

Author

Chen X, Sun T, Shimoda S, Wang H, Huang Q, Fukuda T, and Shi Q

Abstract

Hydrogel-based 3D cell cultures are extensively utilized to create biomimetic cellular microstructures. However, there is still lack of effective method for both evaluation of the complex interaction of cells with hydrogel and the functionality of the resulting micro-structures. This limitation impedes the further application of these microstructures as microphysiological models (microPMs) for the screening of potential culture condition combinations to enhance the skeletal muscle regeneration. This paper introduces a two-probe micromanipulation method for the large-scale assessment of viscoelasticity and contractile force (CF) of skeletal muscle microPMs, which are produced in high-throughput via microfluidic spinning and 96-well culture. The collected data demonstrate that viscoelasticity parameters (E * and tanδ) and CF both measured in a solution environment are indicative of the formation of cellular structures without hydrogel residue and the subsequent generation of myotubes, respectively. This study have developed screening criterias that integrate E * , tanδ, and CF to examine the effects of multifactorial interactions on muscle fiber repair under hypoxic conditions and within bioprinted bipennate muscle structures. This approach has improved the quality of hypoxic threshold evaluation and aligned cell growth in 3D. The proposed method is useful in exploring the role of different factors in muscle tissue regeneration with limited resources., (© 2024 The Author(s). Advanced Science published by Wiley‐VCH GmbH.)

Published
2024
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12. Coupled Systems of Linear Differential-Algebraic and Kinetic Equations with Application to the Mathematical Modelling of Muscle Tissue

Author

Plunder, Steffen, Simeon, Bernd, Ilchmann, Achim, Editor-in-Chief, Reis, Timo, Editor-in-Chief, Biegler, Larry, Editorial Board Member, Campbell, Stephen, Editorial Board Member, Führer, Claus, Editorial Board Member, Gerdts, Matthias, Editorial Board Member, Grundel, Sara, Editorial Board Member, Kunkel, Peter, Editorial Board Member, Linh, Vu Hoang, Editorial Board Member, März, Roswitha, Editorial Board Member, Riaza, Ricardo, Editorial Board Member, Sager, Sebastian, Editorial Board Member, Schöps, Sebastian, Editorial Board Member, Simeon, Bernd, Editorial Board Member, Trenn, Stephan, Editorial Board Member, and Zerz, Eva, Editorial Board Member

Published
2020
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13. A Single Bout of Fatiguing Aerobic Exercise Induces Similar Pronounced Immunological Responses in Both Sexes.

Author

Lobo, Lázaro Fernandes, Morais, Mariana Gomes de, Marcucci-Barbosa, Lucas Soares, Martins-Junior, Francisco de Assis Dias, Avelar, Luíza Martino, Vieira, Erica Leandro Marciano, Aidar, Felipe J., Wanner, Samuel Penna, Silva, Lucélia Scarabeli, Noman, Maria Clara, Camargos, Bruno Muzzi, Freitas, Kátia Michelle, Gonçalves, William Antonio, Pinho, Vanessa, and Nunes-Silva, Albená

Subjects
AMATEUR athletes, AEROBIC capacity, AEROBIC exercises, BODY composition, PSYCHONEUROIMMUNOLOGY, DUAL-energy X-ray absorptiometry, EXERCISE intensity
Abstract

Introduction: Physical exercise can acutely and chronically modulate immunological responses. Women and men have different innate and adaptive immune responses, and in this sense, these two groups may also have different acute immunological responses induced by exercise. In addition, it is essential to understand further whether the effects of physical exercise on the immune system responses depend on sex because limited scientific evidence on this topic is available. This information may allow athletes and coaches to improve the training process, mainly to understand if the physiological impact of given training stimuli in women is similar to that in men. Objective: The present study aimed to investigate the acute effects of continuous submaximal exercise until fatigue on physiological and immunological parameters in amateur female and male runners. Methods: This study included 18 female and 15 male volunteers. Each participant visited the laboratory on four consecutive days. The first visit consisted of medical history taking and explaining the study design. On the second visit, the participants were subjected to an incremental test to determine their maximal rate of oxygen consumption (VO2max) that was required to prescribe the intensity of the submaximal exercise protocol. On the third visit, the fatiguing exercise protocol was performed at 77%–80% of the VO2max. During this submaximal exercise, the heart rate, rating of perceived exertion (RPE), and blood lactate were recorded. Blood samples were collected before, immediately after, and 1 h after the fatiguing protocol to analyze the plasma levels of cytokines and creatine kinase (CK) and to count leukocytes. Finally, on the fourth visit, the participants underwent physical evaluations to measure their body composition using dual-energy X-ray absorptiometry (DXA) imaging. Results: The average ages of the female and male groups were 34.2 ± 3.7 and 30.5 ± 4.3 years old, respectively. The female group ran 57 ± 27 min, while the male group ran 52 ± 15 min before fatiguing. In the female group, when comparing before and after the submaximal exercise, marked increases were observed in the following variables: heart rate (from 68.5 to 180.4 bpm), RPE (from 3.6 to 8.2), lactate (from 2.1 to 4.49 mmol/L), and CK (from 89.5 to 126.3 U/L). In addition, the female group showed an increased number of total leukocytes (from 7222.3 to 11162.9 × 106/μl), neutrophils (from 4,403 to 6,480 × 106/μl), and lymphocytes (from 2,342 ± to 3,562 × 106/μl) from pre- to post-submaximal exercise. In the male group, similar elevations in psychophysiological variables were observed, as evidenced by comparing the heart rate (from 52.8 to 184.1 bpm), RPE (from 0.0 to 8.9), lactate (from 2.7 to 7.2 mmol/L), and CK (from 106.2 to 165 U/L) before and after the submaximal exercise. The male group also showed an augmented number of total leukocytes (from 6,245 to 8,050 × 106/μl), neutrophils (from 3,335 to 4,128 × 106/), and lymphocytes (from 2,191 to 3,212 × 106/μl) when comparing pre- and post-submaximal exercise. There were no differences in the changes between women and men for these parameters. Conclusion: The aerobically fatiguing exercise protocol induced pronounced changes in the heart rate, plasma levels of lactate and CK, total leukocyte count, especially the number of neutrophils and lymphocytes, in both sexes. The fatiguing exercise protocol also changed the plasma levels of IL-6 and IL-10 in the female and male groups. Under the present conditions, the physiological changes induced by fatiguing submaximal exercise, including the immunological changes, were not influenced by sex. This study shows that the same aerobic physical exercise can alter immunological parameters in women and men, and this response is similar between sexes. [ABSTRACT FROM AUTHOR]

Published
2022
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14. A Single Bout of Fatiguing Aerobic Exercise Induces Similar Pronounced Immunological Responses in Both Sexes

Author

Lázaro Fernandes Lobo, Mariana Gomes de Morais, Lucas Soares Marcucci-Barbosa, Francisco de Assis Dias Martins-Junior, Luíza Martino Avelar, Erica Leandro Marciano Vieira, Felipe J. Aidar, Samuel Penna Wanner, Lucélia Scarabeli Silva, Maria Clara Noman, Bruno Muzzi Camargos, Kátia Michelle Freitas, William Antonio Gonçalves, Vanessa Pinho, and Albená Nunes-Silva

Subjects
immune response, myokines, skeletal muscle tissue, physical exercise (running), immunomodulation, Physiology, QP1-981
Abstract

Introduction: Physical exercise can acutely and chronically modulate immunological responses. Women and men have different innate and adaptive immune responses, and in this sense, these two groups may also have different acute immunological responses induced by exercise. In addition, it is essential to understand further whether the effects of physical exercise on the immune system responses depend on sex because limited scientific evidence on this topic is available. This information may allow athletes and coaches to improve the training process, mainly to understand if the physiological impact of given training stimuli in women is similar to that in men.Objective: The present study aimed to investigate the acute effects of continuous submaximal exercise until fatigue on physiological and immunological parameters in amateur female and male runners.Methods: This study included 18 female and 15 male volunteers. Each participant visited the laboratory on four consecutive days. The first visit consisted of medical history taking and explaining the study design. On the second visit, the participants were subjected to an incremental test to determine their maximal rate of oxygen consumption (VO2max) that was required to prescribe the intensity of the submaximal exercise protocol. On the third visit, the fatiguing exercise protocol was performed at 77%–80% of the VO2max. During this submaximal exercise, the heart rate, rating of perceived exertion (RPE), and blood lactate were recorded. Blood samples were collected before, immediately after, and 1 h after the fatiguing protocol to analyze the plasma levels of cytokines and creatine kinase (CK) and to count leukocytes. Finally, on the fourth visit, the participants underwent physical evaluations to measure their body composition using dual-energy X-ray absorptiometry (DXA) imaging.Results: The average ages of the female and male groups were 34.2 ± 3.7 and 30.5 ± 4.3 years old, respectively. The female group ran 57 ± 27 min, while the male group ran 52 ± 15 min before fatiguing. In the female group, when comparing before and after the submaximal exercise, marked increases were observed in the following variables: heart rate (from 68.5 to 180.4 bpm), RPE (from 3.6 to 8.2), lactate (from 2.1 to 4.49 mmol/L), and CK (from 89.5 to 126.3 U/L). In addition, the female group showed an increased number of total leukocytes (from 7222.3 to 11162.9 × 106/μl), neutrophils (from 4,403 to 6,480 × 106/μl), and lymphocytes (from 2,342 ± to 3,562 × 106/μl) from pre- to post-submaximal exercise. In the male group, similar elevations in psychophysiological variables were observed, as evidenced by comparing the heart rate (from 52.8 to 184.1 bpm), RPE (from 0.0 to 8.9), lactate (from 2.7 to 7.2 mmol/L), and CK (from 106.2 to 165 U/L) before and after the submaximal exercise. The male group also showed an augmented number of total leukocytes (from 6,245 to 8,050 × 106/μl), neutrophils (from 3,335 to 4,128 × 106/), and lymphocytes (from 2,191 to 3,212 × 106/μl) when comparing pre- and post-submaximal exercise. There were no differences in the changes between women and men for these parameters.Conclusion: The aerobically fatiguing exercise protocol induced pronounced changes in the heart rate, plasma levels of lactate and CK, total leukocyte count, especially the number of neutrophils and lymphocytes, in both sexes. The fatiguing exercise protocol also changed the plasma levels of IL-6 and IL-10 in the female and male groups. Under the present conditions, the physiological changes induced by fatiguing submaximal exercise, including the immunological changes, were not influenced by sex. This study shows that the same aerobic physical exercise can alter immunological parameters in women and men, and this response is similar between sexes.

Published
2022
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15. Melatonin Potentiates Exercise-Induced Increases in Skeletal Muscle PGC-1 α and Optimizes Glycogen Replenishment.

Author

Faria, Vinícius Silva, Manchado-Gobatto, Fúlvia Barros, Scariot, Pedro Paulo Menezes, Zagatto, Alessandro Moura, and Beck, Wladimir Rafael

Subjects
ANAEROBIC threshold, SKELETAL muscle, GLYCOGEN, EXERCISE tolerance, ACTIVE recovery, MELATONIN
Abstract

Compelling evidence has demonstrated the effect of melatonin on exhaustive exercise tolerance and its modulatory role in muscle energy substrates at the end of exercise. In line with this, PGC-1 α and NRF-1 also seem to act on physical exercise tolerance and metabolic recovery after exercise. However, the literature still lacks reports on these proteins after exercise until exhaustion for animals treated with melatonin. Thus, the aim of the current study was to determine the effects of acute melatonin administration on muscle PGC-1 α and NRF-1, and its modulatory role in glycogen and triglyceride contents in rats subjected to exhaustive swimming exercise at an intensity corresponding to the anaerobic lactacidemic threshold (iLAn). In a randomized controlled trial design, thirty-nine Wistar rats were allocated into four groups: control (CG = 10), rats treated with melatonin (MG = 9), rats submitted to exercise (EXG = 10), and rats treated with melatonin and submitted to exercise (MEXG = 10). Forty-eight hours after the graded exercise test, the animals received melatonin (10 mg/kg) or vehicles 30 min prior to time to exhaustion test in the iLAn (t lim). Three hours after t lim the animals were euthanized, followed by muscle collection for specific analyses: soleus muscles for immunofluorescence, gluteus maximus, red and white gastrocnemius for the assessment of glycogen and triglyceride contents, and liver for the measurement of glycogen content. Student t-test for independent samples, two-way ANOVA, and Newman keuls post hoc test were used. MEXG swam 120.3% more than animals treated with vehicle (EXG; p < 0.01). PGC-1 α and NRF-1 were higher in MEXG with respect to the CG (p < 0.05); however, only PGC-1 α was higher for MEXG when compared to EXG. Melatonin reduced the triglyceride content in gluteus maximus, red and white gastrocnemius (F = 6.66, F = 4.51, and F = 6.02, p < 0.05). The glycogen content in red gastrocnemius was higher in MEXG than in CG (p = 0.01), but not in EXG (p > 0.05). In conclusion, melatonin was found to enhance exercise tolerance, potentiate exercise-mediated increases in PGC-1 α , decrease muscle triglyceride content and increase muscle glycogen 3 h after exhaustive exercise, rapidly providing a better cellular metabolic environment for future efforts. [ABSTRACT FROM AUTHOR]

Published
2022
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16. Processing of Continuous Non‐Crosslinked Collagen Fibers for Microtissue Formation at the Muscle‐Tendon Interface.

Author

Koeck, Kim Sarah, Salehi, Sahar, Humenik, Martin, and Scheibel, Thomas

Subjects
*COLLAGEN, *CONTINUOUS processing, *TISSUE engineering, *EXTRACELLULAR matrix, *MYOBLASTS
Abstract

One of the main components of the extracellular matrix (ECM) in natural tissues is collagen. Therefore, there has been a strong focus on processing of collagen for biomaterials application in tissue engineering such as in anisotropic tissues like muscles and tendons. To achieve native‐like mechanical properties of the in vitro processed collagen, various crosslinking methods have been tested, but the used crosslinkers often do not yield sufficient mechanical properties or induce considerable inflammatory reactions. Here, good mechanical stability of collagen fibers is achieved by self‐assembly during wet‐spinning without the need of additional crosslinkers. The produced endless collagen fibers show fibril alignment within the fiber with a typical D‐band pattern and a periodicity of approximately 67 nm, which is unique for fibril‐forming collagens. Furthermore, the collagen fibers are processed into hierarchical assemblies using textile‐engineering techniques. The woven assemblies are shown to be excellent substrates for the formation of muscle microtissue with long, aligned, and contractile myofibers. Such constructs are highly important at the muscle‐tendon‐junction (MTJ) and therefore myoblasts and fibroblasts are co‐cultured to develop an MTJ‐model. [ABSTRACT FROM AUTHOR]

Published
2022
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17. Human placental mesenchymal stromal cell therapy restores the cytokine efflux and insulin signaling in the skeletal muscle of obesity-induced type 2 diabetes rat model.

Author

Kotikalapudi, Nagasuryaprasad, Sampath, Samuel Joshua Pragasam, Sinha, Sukesh Narayan, Bhonde, R., Mungamuri, Sathish Kumar, and Venkatesan, Vijayalakshmi

Subjects
TYPE 2 diabetes, SKELETAL muscle, STROMAL cells, CELLULAR therapy, INSULIN, MESENCHYMAL stem cells
Abstract

Obesity poses a significant risk factor for the onset of metabolic syndrome with allied complications, wherein mesenchymal stem cell therapy is seen as a promising treatment for obesity-induced metabolic syndrome. In the present study, we aim to explore the beneficial effects of the human placental mesenchymal stromal cells (P-MSCs) on obesity-associated insulin resistance (IR) including inflammation. To understand this, we have analyzed the peripheral blood glucose, serum insulin levels by ELISA, and the glucose uptake capacity of skeletal muscle by a 2-NBDG assay using flow cytometry in WNIN/GR-Ob rats treated with and without P-MSCs. Also, we have studied insulin signaling and cytokine profile in the skeletal muscle by western blotting, dot blotting, and Multiplex-ELISA techniques. The skeletal muscle of WNIN/GR-Ob rats demonstrates dysregulation of cytokines, altered glucose uptake vis-a-vis insulin signaling. However, P-MSCs' treatment was effective in WNIN/GR-Ob rats as compared to its control, to restore HOMA-IR, re-establishes dysregulated cytokines and PI3K-Akt pathway in addition to enhanced Glut4 expression and glucose uptake studied in skeletal muscle. Overall, our data advocate the beneficial effects of P-MSCs to ameliorate inflammatory milieu, improve insulin sensitivity, and normalize glucose homeostasis underlining the Ob-T2D conditions, and we attribute for immunomodulatory, paracrine, autocrine, and multipotent functions of P-MSCs. [ABSTRACT FROM AUTHOR]

Published
2022
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19. 3D Printing of Skeleton Muscle Tissue Engineering Scaffolds.

Author

Song, Ju Qing, Ye, Xin Liang, Chen, Wen Cong, Wang, Li, and Lu, Bing Heng

Subjects
*TISSUE scaffolds, *TISSUE engineering, *THREE-dimensional printing, *BIOMATERIALS, *SKELETON, *SKELETAL muscle
Abstract

The aim of skeletal muscle tissue engineering is to replace or repair skeletal muscle functions that have been injured or lost part of their functions. Skeletal muscle tissue engineering is an important strategy for muscle injury repair. The previous review on skeletal muscle tissue engineering was limited to the discussion of seed cells, biological materials and growth factors. In recent years, research results in this field have continued to emerge. This paper first briefly introduces the anatomy of skeletal muscle, and then combines the latest domestic and foreign study, from the basic problems of tissue engineering skeletal muscle construction to its vascularization, neuralization, etc., to review the current research status of skeletal muscle tissue engineering using three-dimensional (3D) printing, and look forward to its research prospects. [ABSTRACT FROM AUTHOR]

Published
2021
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20. Genistein–a supplement improving efficiency of the human body: A review.

Author

Leis, K., Kulczyńska, A., Racinowski, M., Kaczor, P., Gołębiewski, J., and Januszko-Giergielewicz, B.

Subjects
*GENISTEIN, *ISOFLAVONES, *PHYTOESTROGENS, *POLYPHENOLS, *ADIPOSE tissues
Abstract

In our review, we have compiled and discussed studies relating to the effects of genistein on the efficiency of the human body. Genistein is a compound classified to isoflavones, phytoestrogens and polyphenols. It is found in many products, such as soy, potatoes or beans. (So far, many studies confirming the healthy effects of this compound to the body have been conducted. One of the aspects of genistein is its effect on exercise capacity. It reduces adipose tissue, inhibits cytodifferentiation of adipocytes and also prevents lipogenetic processes. It also lowers cholesterol and triglycerides levels. It shows myoprotective effect, preventing muscle atrophy and damage, and also affects the growth of muscle mass. It reduces the concentration of cortisol, commonly called stress hormone, which has an negative effect on fat metabolism and skeletal muscle. It also supports glucose transport and regulates carbohydrate metabolism, reducing insulin resistance. However, due to estrogen-like action, it lowers testosterone levels. Genistein is a potential nutrient for physically active people. [ABSTRACT FROM AUTHOR]

Published
2021
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21. Varying of up-conversion nanoparticles luminescence from the muscle tissue depth during the compression.

Author

Kozintseva, Marina, Kochubey, Vyacheslav, Konyukhova, Julia, and Tuchin, Valery

Subjects
*LUMINESCENCE, *SKELETAL muscle, *TISSUES, *NANOPARTICLES
Abstract

The current work is focused on the study of optical clearing of skeletal muscles under local compression. The experiments were performed on in vitro bovine skeletal muscle. The time dependence of optical clearing was studied by monitoring the luminescence intensity of NaYF4:Er,Yb upconverting particles located under tissue layers. This study shows the possibility to use upconverting nanoparticles (UCNPs) both for studying the dynamics of the optical clearing of biological tissue under compression and to detect moments of cell wall damage under excessive pressure. The advantage of using UCNPs is the presence of several bands in their luminescence spectra, located both at close wavelengths and far apart. [ABSTRACT FROM AUTHOR]

Published
2021
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22. Nicotinamide Riboside Neutralizes Hypothalamic Inflammation and Increases Weight Loss Without Altering Muscle Mass in Obese Rats Under Calorie Restriction: A Preliminary Investigation

Author

Josimar Macedo de Castro, Dirson João Stein, Helouise Richardt Medeiros, Carla de Oliveira, and Iraci L. S. Torres

Subjects
nicotinamide riboside, caloric restriction, obesity, neuroinflammation, muscle mass, skeletal muscle tissue, Nutrition. Foods and food supply, TX341-641
Abstract

Obesity treatments, such as calorie restriction (CR), eventually lead to muscle wasting and higher rates of neuroinflammation, whereas hypothalamic inflammatory conditions impair body weight (BW) control. Nicotinamide riboside (NR) has been proposed against obesity but with little evidence on skeletal muscle tissue (SMT) and neuroinflammation. Therefore, we aimed to investigate the effects of CR on SMT and on hypothalamic inflammatory biomarkers in obese adult male Wistar rats, and whether NR supplementation alone or in combination with CR affects these parameters. Obesity was induced in rats through a cafeteria diet for 6 weeks. After that, a group of obese rats was exposed to CR, associated or not associated with NR supplementation (400 mg/kg), for another 4 weeks. As a result, obese rats, with or without CR, presented lower relative weight of SMT when compared with eutrophic rats. Rats under CR presented lower absolute SMT weight compared with obese and eutrophic rats, in addition to presenting elevated hypothalamic levels of TNF-α. NR supplementation, in all groups, enhanced weight loss and increased relative weight of the SMT. Furthermore, in animals under CR, NR reversed increases TNF-α levels in the hypothalamus. In this study, these data, although succinct, are the first to evidence the effects of NR on SMT and neuroinflammation when associated with CR, especially in obesity conditions. Therefore, this provides preliminary support for future studies in this investigative field. Furthermore, NR emerges as a potential adjuvant for preventing muscle mass loss in the weight loss processes.

Published
2021
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23. Varying of up-conversion nanoparticles luminescence from the muscle tissue depth during the compression

Author

Marina Kozintseva, Vyacheslav Kochubey, Julia Konyukhova, and Valery Tuchin

Subjects
upconverting particle, biological tissue, skeletal muscle tissue, tissue optical clearing, luminescence imaging technique, mechanical compression, Technology, Optics. Light, QC350-467
Abstract

The current work is focused on the study of optical clearing of skeletal muscles under local compression. The experiments were performed on in vitro bovine skeletal muscle. The time dependence of optical clearing was studied by monitoring the luminescence intensity of NaYF4:Er,Yb upconverting particles located under tissue layers. This study shows the possibility to use upconverting nanoparticles (UCNPs) both for studying the dynamics of the optical clearing of biological tissue under compression and to detect moments of cell wall damage under excessive pressure. The advantage of using UCNPs is the presence of several bands in their luminescence spectra, located both at close wavelengths and far apart.

Published
2021
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24. Impact of visceral adiposity on severity of acute pancreatitis: a propensity score-matched analysis

Author

Jiarong Xie, Lu Xu, Yuning Pan, Peifei Li, Yi Liu, Yue Pan, and Lei Xu

Subjects
Visceral adiposity, Skeletal muscle tissue, Acute pancreatitis, Predictor, Computed tomography, Diseases of the digestive system. Gastroenterology, RC799-869
Abstract

Abstract Background The relationship between visceral adiposity and acute pancreatitis (AP) has not been completely elucidated. This study evaluated the significance of visceral adipose tissue (VAT) and the ratio of VAT to skeletal muscle tissue (VAT/SMT) in the prognosis of AP patients. Methods Based on a 1:2 propensity score matching, 306 hospitalized patients were enrolled in the study analysis from 2010 to 2017. VAT, subcutaneous adipose tissue (SAT), and SMT were measured using unenhanced computed tomography (CT). Cox proportional hazards models were applied for the analysis. Results VAT and the VAT/SMT ratio were significantly higher in the severe AP (SAP) and moderately severe AP (MSAP) groups compared to the mild AP (MAP) group (both p

Published
2019
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25. A Continuum Model of Skeletal Muscle Tissue with Loss of Activation

Author

Giantesio, Giulia, Musesti, Alessandro, Barth, Timothy J., Series Editor, Griebel, Michael, Series Editor, Keyes, David E., Series Editor, Nieminen, Risto M., Series Editor, Roose, Dirk, Series Editor, Schlick, Tamar, Series Editor, Gerisch, Alf, editor, Penta, Raimondo, editor, and Lang, Jens, editor

Published
2017
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26. Muscle Tissue

Author

Rehfeld, Anders, Nylander, Malin, Karnov, Kirstine, Rehfeld, Anders, Nylander, Malin, and Karnov, Kirstine

Published
2017
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27. Miniaturized skeletal muscle tissue fabrication for measuring contractile activity.

Author

Yoshioka, Kantaro, Ito, Akira, Arifuzzaman, Md, Yoshigai, Taichi, Fan, Fangming, Sato, Kei-ichiro, Shimizu, Kazunori, Kawabe, Yoshinori, and Kamihira, Masamichi

Subjects
*SKELETAL muscle, *INDUCED pluripotent stem cells, *MUSCULAR dystrophy, *QUALITY of life, *TISSUES
Abstract

The contractile function of skeletal muscle is essential for maintaining the vital activity of life. Muscular diseases such as muscular dystrophy severely compromise the quality of life of patients and ultimately lead to death. There is therefore an urgent need to develop therapeutic agents for these diseases. In a previous study, we showed that three-dimensional skeletal muscle tissues fabricated using the magnetic force-based tissue engineering technique exhibited contractile activity, and that drug effects could be evaluated based on the contractile activity of the skeletal muscle tissues. However, the reported method requires a large number of cells and the tissue preparation procedure is complex. It is therefore necessary to improve the tissue preparation method. In this study, a miniature device made of polydimethylsiloxane was used to simplify the production of contracting skeletal muscle tissues applicable to high-throughput screening. The effects of model drugs on the contractile force generation of skeletal muscle tissues prepared from mouse C2C12 myoblast and human induced pluripotent stem cells were evaluated using the miniature muscle device. The results indicated that the muscle device system could provide a useful tool for drug screening. [ABSTRACT FROM AUTHOR]

Published
2021
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29. Effects of External Stimulators on Engineered Skeletal Muscle Tissue Maturation.

Author

Mueller, Claudia, Trujillo‐Miranda, Mairon, Maier, Michael, Heath, Daniel E., O'Connor, Andrea J., and Salehi, Sahar

Subjects
SKELETAL muscle, TISSUES, BIOMATERIALS, BIOMIMETIC materials, HYDROGELS
Abstract

Engineering functional skeletal muscle tissue is an ongoing challenge because of the complexity of the in vivo microenvironment and the various factors that contribute to the development and maintenance of the native tissue. However, the growing understanding of the natural skeletal muscle's microenvironment in vivo, as well as the ability to successfully reproduce these factors in vitro, are contributing to the formation of engineered skeletal muscle tissues (SMTs) with greater biomimetic structure and function. This review first summarizes the structure of skeletal muscle tissue. The role of various hydrogels, biomaterials, and scaffolds as building blocks of complex skeletal muscle structures is then explored. Additionally, the role of external stimuli and regulators that can be applied during in vitro culture that lead to the formation of SMT models with higher functionality is examined. These include various physical, biochemical, electrical, mechanical, and magnetic stimulations, as well as biological stimulation through coculture with fibroblasts, endothelial, or neuronal cells. Finally, examples of recently developed functional tissue models that have been developed for in vitro and in vivo applications and the future outlook for this field are discussed. [ABSTRACT FROM AUTHOR]

Published
2021
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30. Assessing the variability of 23Na MRI in skeletal muscle tissue: Reproducibility and repeatability of tissue sodium concentration measurements in the lower leg at 3 T.

Author

Gerhalter, Teresa, Gast, Lena V., Marty, Benjamin, Uder, Michael, Carlier, Pierre G., and Nagel, Armin M.

Subjects
SKELETAL muscle, STATISTICAL reliability, SODIUM, BLAND-Altman plot, TISSUES
Abstract

The goal of this study was to evaluate the reproducibility and repeatability of tissue sodium concentration (TSC) measurements using 23Na MRI in skeletal muscle tissue. 23Na MRI was performed at 3 T on the right lower leg of eight healthy volunteers (aged 28 ± 4 years). The examinations were repeated at the same site after ~ 22 weeks to assess the variability over a medium‐term period. Additionally, they were scanned at a second site shortly before or shortly after the first visit (within 3 weeks) to evaluate the inter‐site reproducibility. Moreover, we analysed the effect of B0 correction on the variability. Coefficients of variations (CVs) from mean TSC values as well as Bland–Altman plots were used to assess intra‐site repeatability and inter‐site reproducibility. In phantom measurements, the B0 correction improved the quantitative accuracy. We observed differences of up to 4.9 mmol/L between the first and second visit and a difference of up to 3.7 mmol/L between the two different sites. The CV for the medium‐term repeatability was 15% and the reproducibility CV was 9%. The Bland–Altman plots indicated high agreement between the visits in all muscle regions. The systematic bias of −0.68 mmol/L between site X and Y (P = 0.03) was slightly reduced to −0.64 mmol/L after B0 correction (P = 0.04). This work shows that TSC measurements in healthy skeletal muscle tissue can be performed with good repeatability and reproducibility, which is of importance for future longitudinal or multicentre studies. [ABSTRACT FROM AUTHOR]

Published
2020
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32. A mini review on 3-D bioprinting in skeletal muscle tissue engineering

Author

Punit Fulzele, Zahiruddin Quazi Syed, A. V. Raut, Ashutosh Bagde, and Akhilesh Agrawal

Subjects
Bone marrow transplant, Engineering, business.industry, Mechanical strength, Skeletal Muscle Tissue, General Medicine, business, Mini review, Biomedical engineering, Skeletal tissue
Abstract

This review focuses on advances in the field of bioprinting for skeletal tissue engineering, as well as a discussion of various bone marrow transplants. All methods (cellular, non-cellular and both) are aimed at finding complex living tissues capable of growing and maturing, using the same basic technology. To date, co-printing of cellular and non-cellular material has been identified as the most promising method for muscle applications because materials with good performance and good mechanical strength can be integrated within the same structure. Integration of orthopedic applications is an evolving field, and a detailed discussion of current challenges and ideas for the future is also presented in this review.

Published
2023

34. SKELETAL MUSCLE POSTTRAUMATIC REGENERATION RESPONSE TO HUMIC PELOID MEDICATION.

Author

SUVOROVA, Galina N., VOLOGDINA, Natalia N., AVVAKUMOV, Nadezhda P., and KRIVOPALOVA, Maria Y.

Subjects
*SKELETAL muscle, *HUMUS, *HUMIC acid, *ZINC ions, *LABORATORY rats, *MICROSCOPY
Abstract

One of the relevant tasks of current morphology is the investigation of tissue regenerative potential and research for new medications that improve recovery process efficiency. Nowadays, clinical specialists focus on medications that are based on natural compounds. However, such medication influence on the processes that occur within the injured tissues is still not identified. The purpose of this study was to investigate skeletal muscle tissue posttraumatic regeneration response to humic peloid medication, based on humic acids modified by Zinc ions. Humic acid extraction was carried out by means of patent procedure. The study included laboratory Wistar rats with hyperextension of front femur muscle. The preparations were studied by means of light and electronic microscopy and autoradiography. Histologic preparations evaluation showed that under peloid medication exposure the apolexis processes within muscle fibers rupture are inhibited, interstitial edema becomes restricted by the injured area, vessel growth into the area of damaged capillaries is stimulated, macrophages migrate and the area and duration of posttraumatic inflammation decrease. Additionally, peloid medication intake shortens the length of skeletal muscle tissue reparative histogenesis stages: myosatellitocytes are activated earlier than in the control group, myoblasts and myosymplasts are detected, the separation of nuclear sarcoplasmatic areas from partly injured muscle fibers is stimulated, myotubules appear 3 - 5 days earlier than in control group. Overall, muscle tissue regeneration efficiency increases by 21%. Obtained results allow us to conclude that peloid medication based on humic acids modified by Zinc ions positively influence the stimulation of the regeneration process. This will lead to further investigation of humic substances: fulvic, hymatomelanic, humin and humic acids of peloids as medications and their implementation in clinical practice. [ABSTRACT FROM AUTHOR]

Published
2019
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35. Anisotropic composite material phantom to improve skeletal muscle characterization using magnetic resonance elastography.

Author

Guidetti, Martina, Lorgna, Gloria, Klatt, Dieter, Vena, Pasquale, and Royston, Thomas J.

Subjects
SKELETAL muscle, ELASTOGRAPHY, MAGNETIC resonance imaging, TISSUE mechanics, VISCOELASTICITY, COMPOSITE materials, ANISOTROPY
Abstract

Abstract The presence and progression of neuromuscular pathology, including spasticity, Duchenne's muscular dystrophy and hyperthyroidism, has been correlated with changes in the intrinsic mechanical properties of skeletal muscle tissue. Tools for noninvasively measuring and monitoring these properties, such as Magnetic Resonance Elastography (MRE), could benefit basic research into understanding neuromuscular pathologies, as well as translational research to develop therapies, by providing a means of assessing and tracking their efficacy. Dynamic elastography methods for noninvasive measurement of tissue mechanical properties have been under development for nearly three decades. Much of the technological development to date, for both Ultrasound (US)-based and Magnetic Resonance Imaging (MRI)-based strategies, has been grounded in assumptions of local homogeneity and isotropy. Striated skeletal and cardiac muscle, as well as brain white matter and soft tissue in some other organ regions, exhibit a fibrous microstructure which entails heterogeneity and anisotropic response; as one seeks to improve the accuracy and resolution in mechanical property assessment, heterogeneity and anisotropy need to be accounted for in order to optimize both the dynamic elastography experimental protocol and the interpretation of the measurements. Advances in elastography methodology at every step have been aided by the use of tissue-mimicking phantoms. The aim of the present study was to develop and characterize a heterogeneous composite phantom design with uniform controllable anisotropic properties meant to be comparable to the frequency-dependent anisotropic properties of skeletal muscle. MRE experiments and computational finite element (FE) studies were conducted on a novel 3D-printed composite phantom design. The displacement maps obtained from simulation and experiment show the same elliptical shaped wavefronts elongated in the plane where the structure presents higher shear modulus. The model exhibits a degree of anisotropy in line with literature data from skeletal muscle tissue MRE experiments. FE simulations of the MRE experiments provide insight into proper interpretation of experimental measurements, and help to quantify the importance of heterogeneity in the anisotropic material at different scales. Graphical abstract fx1 Highlights • In this study composite phantoms were designed for MRE; they exhibited anisotropic heterogeneous viscoelastic properties. • The degree of anisotropy found in MRE experiments and FE simulations is comparable with values for muscle from literature. • The study of anisotropic viscoelastic materials may lead to improvements in the identification of disease-correlated changes. [ABSTRACT FROM AUTHOR]

Published
2019
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36. Стан скелетної м’язової тканини в жінок української популяції

Author

A. A. Tkachuk, A.S. Belinska, Vladyslav Povoroznyuk, and N.I. Dzerovych

Subjects
education.field_of_study, medicine.medical_specialty, business.industry, Population, Skeletal muscle, medicine.disease, medicine.anatomical_structure, Weight loss, Sarcopenia, Skeletal Muscle Tissue, Physical therapy, Medicine, medicine.symptom, business, education, Whole body
Abstract

Today among geriatric syndromes, world scientists pay much attention to the study of sarcopenia. It was found that the evaluation of skeletal muscle strength has a significant correlation with the risk of falls, disability, deterioration in the quality of life, duration of hospitalization. It is proved that measurements of skeletal muscle strength, but not the determination of skeletal muscles mass, are strong and independent predictors of mortality in the elderly. Further researches are needed to study the characteristics of weight loss, strength and function of skeletal muscle with age in individuals of different sex and age. The objective of this study was to explore the features of strength and functionality of skeletal muscle tissue in women of all ages. The study involved 248 women, who were divided into groups by decades depending on age: 20–29, 30–39, 40–49, 50–59, 60–69, 70–79, 80–89 years. Skeletal muscle strength was evaluated using spring carpal dynamometer. Functions of skeletal muscles and the risk of falls were assessed using special tests. Fat-free mass of the whole body, upper and lower extremities was evaluated by means of dual-energy X-ray absorptiometry (Prodigy, GEHC Lunar, Madison, WI, USA). The study found that maximal values of strength and functional capacity of skeletal muscles were observed in women in the age group of 20–29 years. The significant loss of skeletal muscle strength is being detected in individuals from the age group of 60–69 years and older. When determining the functional capacity of skeletal muscles and risk of falls, significantly worse performance was established in women older than 50 years compared to those in women in the age group of 20–29 years.

Published
2022

37. Effective MSTN Gene Knockout by AdV-Delivered CRISPR/Cas9 in Postnatal Chick Leg Muscle

Author

Ke Xu, Cheng Xiao Han, Hao Zhou, Jin Mei Ding, Zhong Xu, Ling Yu Yang, Chuan He, Fisayo Akinyemi, Yu Ming Zheng, Chao Qin, Huai Xi Luo, and He Meng

Subjects
myostatin, CRISPR/Cas9, knockout, postnatal gene editing, transcriptome sequencing, skeletal muscle tissue, Biology (General), QH301-705.5, Chemistry, QD1-999
Abstract

Muscle growth and development are important aspects of chicken meat production, but the underlying regulatory mechanisms remain unclear and need further exploration. CRISPR has been used for gene editing to study gene function in mice, but less has been done in chick muscles. To verify whether postnatal gene editing could be achieved in chick muscles and determine the transcriptomic changes, we knocked out Myostatin (MSTN), a potential inhibitor of muscle growth and development, in chicks and performed transcriptome analysis on knock-out (KO) muscles and wild-type (WT) muscles at two post-natal days: 3d (3-day-old) and 14d (14-day-old). Large fragment deletions of MSTN (>5 kb) were achieved in all KO muscles, and the MSTN gene expression was significantly downregulated at 14d. The transcriptomic results indicated the presence of 1339 differentially expressed genes (DEGs) between the 3d KO and 3d WT muscles, as well as 597 DEGs between 14d KO and 14d WT muscles. Many DEGs were found to be related to cell differentiation and proliferation, muscle growth and energy metabolism. This method provides a potential means of postnatal gene editing in chicks, and the results presented here could provide a basis for further investigation of the mechanisms involved in muscle growth and development.

Published
2020
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38. Global Evolution of Skeletal Muscle Tissue Engineering: A Scientometric Research

Author

Haowen Qiao, Xincheng Du, Jiayu Yan, Xingdao He, Wenwen Liu, Fang Xu, Gaozhi Ou, and Xingping Qin

Subjects
Tissue Engineering, Bioprinting, Biomedical Engineering, Skeletal Muscle Tissue, Humans, Medicine (miscellaneous), Bioengineering, Global evolution, Biology, Muscle, Skeletal, Data science
Abstract

Skeletal muscle tissue engineering (SMTE) is of great significance in the study of skeletal muscle physiology and pathology, which could be used in skeletal muscle graft. The scientometric analysis of SMTE can help researchers to quickly understand the evolutive history, status, novelties, and trend of this field. In this study, we performed a scientometric study that can be used to construct and visualize networks of SMTE using VOSviewer. A total of 1384 documents published between 1994 and 2020 were retrieved and analyzed. Our results showed that number of publications in SMTE has increased slowly from 1994 to 2014 and has increased rapidly from 2015 to 2020. The geographical distribution of publications in terms of total publications about SMTE is concentrated in Europe and the United States. The most productive institution was University of Michigan, while Harvard University and the University of Pittsburgh were ranked the second and third places. SMTE influenced a wide spectrum of disciplines, including Biology and Medicine and Physical Sciences. In addition, the research hotspot of SMTE was expanding from seed cells to the combination with advanced strategies (electrostatic spinning, bioprinting, and materials) for emulating the highly bionic engineered skeletal muscle tissues. This study provided a unique perspective for understanding the history and trends of SMTE, which could help to promote the rapid development of the field. Impact statement Skeletal muscle tissue engineering (SMTE), which acts as an important branch of tissue engineering, hold a great promise in the study of skeletal muscle physiology and pathology. The field of SMTE has developed rapidly in recent decades while still lacking studies based on scientometric methods. This article provided the first scientometric study of SMTE from development trends and evolution of the field. The results indicated that the field of SMTE was experiencing rapid growth and had a significant impact on multiple fields, particularly in Biology and Medicine and Physical Sciences.

Published
2021

39. Impact of Human Epidermal Growth Factor on Tissue-Engineered Skeletal Muscle Structure and Function

Author

Paul S. Cederna, Lisa M. Larkin, Olga M Wroblewski, Emmanuel E Vega-Soto, and Matthew H. Nguyen

Subjects
Muscle tissue, Tissue engineered, Epidermal Growth Factor, Tissue Engineering, Muscle loss, Human epidermal growth factor, Muscle Fibers, Skeletal, Biomedical Engineering, Cell Differentiation, Bioengineering, Original Articles, Skeletal muscle structure, Biology, Muscle Development, Biochemistry, Regenerative medicine, Cell biology, Biomaterials, medicine.anatomical_structure, Skeletal Muscle Tissue, medicine, Humans, Muscle, Skeletal, Function (biology)
Abstract

Skeletal muscle tissue engineering technologies have the potential to treat volumetric muscle loss (VML) by growing exogenous muscle tissue. However, there has been limited success in engineering human cell-sourced skeletal muscle with structure and function comparable to native adult human muscle. The use of growth factors at optimal concentrations and delivery times is critical in enhancing the in vitro myogenesis of satellite cells used in engineered skeletal muscle. The mitogenic protein human epidermal growth factor (hEGF) is of particular interest because it enhances satellite cell proliferation and sarcomeric structure formation in myogenic cell cultures. In this study, we used our scaffold-free tissue-engineered skeletal muscle units (SMUs) to examine the effects of hEGF on the structure and function of human cell-sourced engineered skeletal muscle. During our established SMU fabrication process, human muscle cell isolates were exposed to media treated with 7.5 nM hEGF at three different time spans during the 21-day cell culture period: 0 to 6 days postseeding (hEGF-treated Muscle Growth Media [MGM] Only), 7 to 21 days postseeding (hEGF-treated Muscle Differentiation Media (MDM) Only), and 0 to 21 days postseeding (hEGF-treated MGM+MDM). Control cell cultures were fed standard MGM and MDM (no hEGF treatment). During the fabrication process, light microscopy was used to examine proliferation and differentiation of myogenic cells in the monolayer. After SMU formation, the three-dimensional constructs underwent tetanic force production measurements to evaluate contractile function and immunohistochemical staining to examine SMU structure. Results indicated that hEGF administration impacted myogenesis, by increasing myotube diameter in hEGF-treated MGM only and hEGF-treated MDM-only cell cultures, and by increasing myotube density in hEGF-treated MGM+MDM cultures. The exposure of myogenic cells to hEGF during any time period of the fabrication process led to a significant increase in SMU myosin heavy-chain content. SMUs exposed to hEGF-treated MDM and hEGF-treated MGM+MDM exhibited greater cross-sectional areas and more organized sarcomeric structure. Furthermore, hEGF-treated MGM+MDM SMUs displayed significantly enhanced contractile function compared with controls, indicating advanced functional maturation. In conclusion, hEGF supplementation in human primary myogenic cell cultures advances tissue-engineered skeletal muscle structural and functional characteristics. IMPACT STATEMENT: Our research suggests that human epidermal growth factor (hEGF) serves as a critical growth factor in enhancing in vitro skeletal muscle cell proliferation and differentiation during myogenesis and advances human skeletal muscle engineered tissues toward a more native adult skeletal muscle phenotype. Understanding the impact of hEGF on engineered skeletal muscle function and structure is valuable in determining the optimal culture conditions for the development of tissue engineering-based therapies for volumetric muscle loss.

Published
2021

42. Preservative solution for skeletal muscle biopsy samples

Author

Yasemin Gulcan Kurt, Bulent Kurt, Omer Ozcan, Turgut Topal, Abdullah Kilic, Tuba Muftuoglu, Cengizhan Acikel, Kenan Sener, Fatih Sahiner, Nuri Yigit, Ibrahim Aydin, Semih Alay, and Safak Ekinci

Subjects
Enzyme activity, morphology, mRNA, preservative solution, skeletal muscle tissue, Neurology. Diseases of the nervous system, RC346-429
Abstract

Context : Muscle biopsy samples must be frozen with liquid nitrogen immediately after excision and maintained at -80 o C until analysis. Because of this requirement for tissue processing, patients with neuromuscular diseases often have to travel to centers with on-site muscle pathology laboratories for muscle biopsy sample excision to ensure that samples are properly preserved. Aim: Here, we developed a preservative solution and examined its protectiveness on striated muscle tissues for a minimum of the length of time that would be required to reach a specific muscle pathology laboratory. Materials and Methods: A preservative solution called Kurt-Ozcan (KO) solution was prepared. Eight healthy Sprague-Dawley rats were sacrificed; striated muscle tissue samples were collected and divided into six different groups. Muscle tissue samples were separated into groups for morphological, enzyme histochemical, molecular, and biochemical analysis. Statistical method used: Chi-square and Kruskal Wallis tests. Results: Samples kept in the KO and University of Wisconsin (UW) solutions exhibited very good morphological scores at 3, 6, and 18 hours, but artificial changes were observed at 24 hours. Similar findings were observed for the evaluated enzyme activities. There were no differences between the control group and the samples kept in the KO or UW solution at 3, 6, and 18 hours for morphological, enzyme histochemical, and biochemical features. The messenger ribonucleic acid (mRNA) of β-actin gene was protected up to 6 hours in the KO and UW solutions. Conclusion: The KO solution protects the morphological, enzyme histochemical, and biochemical features of striated muscle tissue of healthy rats for 18 hours and preserves the mRNA for 6 hours.

Published
2015
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43. Shared gene expression signatures between visceral adipose and skeletal muscle tissues are associated with cardiometabolic traits in children with obesity.

Author

Bustos-Aibar M, Aguilera CM, Alcalá-Fdez J, Ruiz-Ojeda FJ, Plaza-Díaz J, Plaza-Florido A, Tofe I, Gil-Campos M, Gacto MJ, and Anguita-Ruiz A

Subjects
Male, Humans, Child, Transcriptome genetics, Gene Expression Profiling, Intra-Abdominal Fat metabolism, Intra-Abdominal Fat pathology, Muscle, Skeletal, Protein Tyrosine Phosphatases, Non-Receptor metabolism, Pediatric Obesity genetics, Pediatric Obesity complications, Pediatric Obesity metabolism, Cardiovascular Diseases pathology
Abstract

Obesity in children is related to the development of cardiometabolic complications later in life, where molecular changes of visceral adipose tissue (VAT) and skeletal muscle tissue (SMT) have been proven to be fundamental. The aim of this study is to unveil the gene expression architecture of both tissues in a cohort of Spanish boys with obesity, using a clustering method known as weighted gene co-expression network analysis. For this purpose, we have followed a multi-objective analytic pipeline consisting of three main approaches; identification of gene co-expression clusters associated with childhood obesity, individually in VAT and SMT (intra-tissue, approach I); identification of gene co-expression clusters associated with obesity-metabolic alterations, individually in VAT and SMT (intra-tissue, approach II); and identification of gene co-expression clusters associated with obesity-metabolic alterations simultaneously in VAT and SMT (inter-tissue, approach III). In both tissues, we identified independent and inter-tissue gene co-expression signatures associated with obesity and cardiovascular risk, some of which exceeded multiple-test correction filters. In these signatures, we could identify some central hub genes (e.g., NDUFB8, GUCY1B1, KCNMA1, NPR2, PPP3CC) participating in relevant metabolic pathways exceeding multiple-testing correction filters. We identified the central hub genes PIK3R2, PPP3C and PTPN5 associated with MAPK signaling and insulin resistance terms. This is the first time that these genes have been associated with childhood obesity in both tissues. Therefore, they could be potential novel molecular targets for drugs and health interventions, opening new lines of research on the personalized care in this pathology. This work generates interesting hypotheses about the transcriptomics alterations underlying metabolic health alterations in obesity in the pediatric population., Competing Interests: Declaration of competing interest The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: C.M. Aguilera reports financial support was provided by ERDF, Health Institute Carlos III, Spanish Ministry of Science. J. Alcala-Fdez reports financial support was provided by ERDF, Regional Government of Andalusia, Ministry of Economic Transformation, Industry, Knowledge and Universities., (Copyright © 2023 The Author(s). Published by Elsevier Ltd.. All rights reserved.)

Published
2023
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46. Intracellular-to-total water ratio explains the variability of muscle strength dependence on the size of the lower leg in the elderly.

Author

Yoshida, Tsukasa, Yamada, Yosuke, Tanaka, Fumiko, Yamagishi, Takaki, Shibata, Shigenobu, and Kawakami, Yasuo

Subjects
*MUSCLE strength, *BIOELECTRIC impedance, *ULTRASONIC imaging, *ISOMETRIC exercise, *DORSIFLEXION
Abstract

Abstract Bioelectrical impedance spectroscopy (BIS) can assess intracellular water (ICW) and total water (TW) in limbs. This study aimed to examine whether BIS can explain a part of the inter-individual variation of the muscle size-strength relationship in older adults. We analyzed the data of 79 participants aged 64–86 years. The maximal voluntary isometric torques of dorsiflexion and plantar flexion on the right side were measured. The anterior and posterior muscle thickness (MT) in the right lower leg was assessed using ultrasonography. The length of the right lower leg (L) was measured, and the ICW-to-TW ratio (ICW/TW) in the right lower leg was obtained using BIS. The MT was multiplied by L to represent an index of muscle volume (MV). Correlation and stepwise regression analyses were performed. The anterior and posterior MT × L significantly and positively correlated with the muscle torque of dorsiflexion and plantar flexion (r = 0.710 and 0.649, respectively, P < 0.001). In the stepwise regression analyses, ICW/TW was selected as a significant predictor of muscle torque independent of MT × L (P < 0.05) for both dorsiflexion and plantar flexion. Electrical parameters of BIS (membrane capacitance, characteristics frequency, and phase angle) in the lower leg also significantly correlated with muscle torques. In addition, the skeletal muscle mass index (appendicular lean mass/height2) was also associated with ICW/TW (P < 0.001). The present results suggest that ICW/TW explains the interindividual variations of the muscle size-strength relationship. Highlights • Muscle strength is related to intracellular-total water ratio (ICW/TW) obtained by bioelectrical impedance spectroscopy (BIS). • ICW/TW is positively associated with muscle strength independent of the muscle volume index obtained by ultrasonography. • ICW/TW and other electrical properties of BIS can be good markers of muscle quality in the elderly. • Combined ultrasonography and BIS is useful to assess muscle mass and quality. [ABSTRACT FROM AUTHOR]

Published
2018
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