Mechanobiology in Tendon, Ligament, and Skeletal Muscle Tissue Engineering

2021 ◽  
Vol 143 (7) ◽  
Author(s):  
Michael T. K. Bramson ◽  
Sarah K. Van Houten ◽  
David T. Corr
Keyword(s):  
Skeletal Muscle ◽  
Tissue Engineering ◽  
Mechanical Loading ◽  
Mechanical Stimulation ◽  
Self Assembly ◽  
Tissue Constructs ◽  
Active Contraction ◽  
Matrix Production

Abstract Tendon, ligament, and skeletal muscle are highly organized tissues that largely rely on a hierarchical collagenous matrix to withstand high tensile loads experienced in activities of daily life. This critical biomechanical role predisposes these tissues to injury, and current treatments fail to recapitulate the biomechanical function of native tissue. This has prompted researchers to pursue engineering functional tissue replacements, or dysfunction/disease/development models, by emulating in vivo stimuli within in vitro tissue engineering platforms—specifically mechanical stimulation, as well as active contraction in skeletal muscle. Mechanical loading is critical for matrix production and organization in the development, maturation, and maintenance of native tendon, ligament, and skeletal muscle, as well as their interfaces. Tissue engineers seek to harness these mechanobiological benefits using bioreactors to apply both static and dynamic mechanical stimulation to tissue constructs, and induce active contraction in engineered skeletal muscle. The vast majority of engineering approaches in these tissues are scaffold-based, providing interim structure and support to engineered constructs, and sufficient integrity to withstand mechanical loading. Alternatively, some recent studies have employed developmentally inspired scaffold-free techniques, relying on cellular self-assembly and matrix production to form tissue constructs. Whether utilizing a scaffold or not, incorporation of mechanobiological stimuli has been shown to improve the composition, structure, and biomechanical function of engineered tendon, ligament, and skeletal muscle. Together, these findings highlight the importance of mechanobiology and suggest how it can be leveraged to engineer these tissues and their interfaces, and to create functional multitissue constructs.

scholarly journals Mechanical loading of tissue engineered skeletal muscle prevents dexamethasone induced myotube atrophy

2020 ◽  
Author(s):  
Kathryn W. Aguilar-Agon ◽  
Andrew J. Capel ◽  
Jacob W. Fleming ◽  
Darren J. Player ◽  
Neil R. W. Martin ◽  
...  
Keyword(s):  
Skeletal Muscle ◽  
Mechanical Loading ◽  
Muscle Atrophy ◽  
Mechanical Load ◽  
3D Models ◽  
Skeletal Muscle Atrophy ◽  
Treatment Modalities ◽  
Murine Cell Line

Abstract Skeletal muscle atrophy as a consequence of acute and chronic illness, immobilisation, muscular dystrophies and aging, leads to severe muscle weakness, inactivity and increased mortality. Mechanical loading is thought to be the primary driver for skeletal muscle hypertrophy, however the extent to which mechanical loading can offset muscle catabolism has not been thoroughly explored. In vitro 3D-models of skeletal muscle provide a controllable, high throughput environment and mitigating many of the ethical and methodological constraints present during in vivo experimentation. This work aimed to determine if mechanical loading would offset dexamethasone (DEX) induced skeletal muscle atrophy, in muscle engineered using the C2C12 murine cell line. Mechanical loading successfully offset myotube atrophy and functional degeneration associated with DEX regardless of whether the loading occurred before or after 24 h of DEX treatment. Furthermore, mechanical load prevented increases in MuRF-1 and MAFbx mRNA expression, critical regulators of muscle atrophy. Overall, we demonstrate the application of tissue engineered muscle to study skeletal muscle health and disease, offering great potential for future use to better understand treatment modalities for skeletal muscle atrophy.

Collagen/silica nanocomposites and hybrids for bone tissue engineering

2013 ◽  
Vol 2 (4) ◽  
pp. 427-447 ◽  
Author(s):  
Bapi Sarker ◽  
Stefan Lyer ◽  
Andreas Arkudas ◽  
Aldo R. Boccaccini
Keyword(s):  
Tissue Engineering ◽  
Bone Tissue Engineering ◽  
Bone Tissue ◽  
Self Assembly ◽  
Structural Integrity ◽  
Organic Matrix ◽  
Angiogenic Potential ◽  
Silica Nanocomposites

AbstractCollagen is increasingly attracting attention for bone tissue engineering applications. However, due to its low mechanical properties, applications including mechanical loads or requiring structural integrity are limited. To tackle this handicap, collagen can be combined with (nanoscale) silica in a variety of composite materials that are attractive for bone tissue engineering. Considering research carried out in the past 15 years, this article reviews the literature discussing the development of silica/collagen composites that have been synthesized by adding silica from different sources as inorganic bioactive material to collagen as organic matrix. Different routes for the fabrication of collagen/silica composites are presented, focusing on nanocomposites. In vitro cell bioactivity studies demonstrated the osteogenic and, in some cases, angiogenic potential of the composites. Relevant in vivo studies discussing integration of the materials in bone tissue are discussed. Due to the understanding of possible interaction between silicon species and collagen, the effect of different silica precursors on the collagen self-assembly process is also discussed. On the basis of literature results and as discussed in this review, collagen/silica nanocomposites and hybrids represent attractive biomaterials for bone regeneration applications.

scholarly journals 3D Hepatic Organoid-Based Advancements in LIVER Tissue Engineering

2021 ◽  
Vol 8 (11) ◽  
pp. 185
Author(s):  
Amit Panwar ◽  
Prativa Das ◽  
Lay Poh Tan
Keyword(s):  
Tissue Engineering ◽  
Self Assembly ◽  
Liver Tissue ◽  
3D Culture ◽  
Culture Method ◽  
Culture Conditions ◽  
Phenotypic Properties ◽  
Liver Tissue Engineering

Liver-associated diseases and tissue engineering approaches based on in vitro culture of functional Primary human hepatocytes (PHH) had been restricted by the rapid de-differentiation in 2D culture conditions which restricted their usability. It was proven that cells growing in 3D format can better mimic the in vivo microenvironment, and thus help in maintaining metabolic activity, phenotypic properties, and longevity of the in vitro cultures. Again, the culture method and type of cell population are also recognized as important parameters for functional maintenance of primary hepatocytes. Hepatic organoids formed by self-assembly of hepatic cells are microtissues, and were able to show long-term in vitro maintenance of hepato-specific characteristics. Thus, hepatic organoids were recognized as an effective tool for screening potential cures and modeling liver diseases effectively. The current review summarizes the importance of 3D hepatic organoid culture over other conventional 2D and 3D culture models and its applicability in Liver tissue engineering.

scholarly journals Human Organ-Specific 3D Cancer Models Produced by the Stromal Self-Assembly Method of Tissue Engineering for the Study of Solid Tumors

2020 ◽  
Vol 2020 ◽  
pp. 1-23 ◽  
Author(s):  
Vincent Roy ◽  
Brice Magne ◽  
Maude Vaillancourt-Audet ◽  
Mathieu Blais ◽  
Stéphane Chabaud ◽  
...  
Keyword(s):  
Tissue Engineering ◽  
Tumor Microenvironment ◽  
Self Assembly ◽  
The Self ◽  
Human Organ ◽  
Assembly Method ◽  
Cancer Models ◽  
Organ Specific

Cancer research has considerably progressed with the improvement of in vitro study models, helping to understand the key role of the tumor microenvironment in cancer development and progression. Over the last few years, complex 3D human cell culture systems have gained much popularity over in vivo models, as they accurately mimic the tumor microenvironment and allow high-throughput drug screening. Of particular interest, in vitrohuman 3D tissue constructs, produced by the self-assembly method of tissue engineering, have been successfully used to model the tumor microenvironment and now represent a very promising approach to further develop diverse cancer models. In this review, we describe the importance of the tumor microenvironment and present the existing in vitro cancer models generated through the self-assembly method of tissue engineering. Lastly, we highlight the relevance of this approach to mimic various and complex tumors, including basal cell carcinoma, cutaneous neurofibroma, skin melanoma, bladder cancer, and uveal melanoma.

Tissue Engineering of Fibroblast Constructs and Anisotropic Collagen Gels

2002 ◽  
Vol 724 ◽  
Author(s):  
Sarah Calve ◽  
Ellen Arruda ◽  
Robert Dennis ◽  
Karl Grosh ◽  
Krystyna Pasyk
Keyword(s):  
Tissue Engineering ◽  
Self Assembly ◽  
Cell Layer ◽  
Fetal Bovine Serum ◽  
Self Organization ◽  
Collagen Gels ◽  
Confluent Cell ◽  
Fetal Bovine

AbstractThe creation of an in vitro functional tendon construct will enable testing of the influence of mechanics and nutrients on the development and remodeling of tendon under known controlled stimuli which is difficult to achieve in vivo. Tendon constructs were engineered in vitrovia stress-mediated self organization of fibroblasts and ECM on a laminin coated elastomer substrate. Varying the laminin density and the amount of fetal bovine serum on the substrate affected the ability of tendon fibroblasts to form a confluent cell layer and the time to layer delamination. Understanding the factors that promote self-assembly of tendon constructs will enable their combination with already developed in vitro muscle constructs.

scholarly journals Ether-Oxygen Containing Electrospun Microfibrous and Sub-Microfibrous Scaffolds Based on Poly(butylene 1,4-cyclohexanedicarboxylate) for Skeletal Muscle Tissue Engineering

2018 ◽  
Vol 19 (10) ◽  
pp. 3212 ◽  
Author(s):  
Nora Bloise ◽  
Emanuele Berardi ◽  
Chiara Gualandi ◽  
Elisa Zaghi ◽  
Matteo Gigli ◽  
...  
Keyword(s):  
Skeletal Muscle ◽  
Tissue Engineering ◽  
Muscle Tissue ◽  
Skeletal Muscle Tissue ◽  
Cell Alignment ◽  
Fibre Direction ◽  
Electrospun Scaffolds ◽  
Fibre Morphology

We report the study of novel biodegradable electrospun scaffolds from poly(butylene 1,4-cyclohexandicarboxylate-co-triethylene cyclohexanedicarboxylate) (P(BCE-co-TECE)) as support for in vitro and in vivo muscle tissue regeneration. We demonstrate that chemical composition, i.e., the amount of TECE co-units (constituted of polyethylene glycol-like moieties), and fibre morphology, i.e., aligned microfibrous or sub-microfibrous scaffolds, are crucial in determining the material biocompatibility. Indeed, the presence of ether linkages influences surface wettability, mechanical properties, hydrolytic degradation rate, and density of cell anchoring points of the studied materials. On the other hand, electrospun scaffolds improve cell adhesion, proliferation, and differentiation by favouring cell alignment along fibre direction (fibre morphology), also allowing for better cell infiltration and oxygen and nutrient diffusion (fibre size). Overall, C2C12 myogenic cells highly differentiated into mature myotubes when cultured on microfibres realised with the copolymer richest in TECE co-units (micro-P73 mat). Lastly, when transplanted in the tibialis anterior muscles of healthy, injured, or dystrophic mice, micro-P73 mat appeared highly vascularised, colonised by murine cells and perfectly integrated with host muscles, thus confirming the suitability of P(BCE-co-TECE) scaffolds as substrates for skeletal muscle tissue engineering.

scholarly journals Design and Validation of Equiaxial Mechanical Strain Platform, EQUicycler, for 3D Tissue Engineered Constructs

2017 ◽  
Vol 2017 ◽  
pp. 1-12 ◽  
Author(s):  
Mostafa Elsaadany ◽  
Matthew Harris ◽  
Eda Yildirim-Ayan
Keyword(s):  
Cell Lines ◽  
Mechanical Loading ◽  
Mechanical Load ◽  
Mechanical Strain ◽  
Three Dimensional ◽  
Cost Effective ◽  
Tissue Constructs ◽  
Tissue Systems

It is crucial to replicate the micromechanical milieu of native tissues to achieve efficacious tissue engineering and regenerative therapy. In this study, we introduced an innovative loading platform, EQUicycler, that utilizes a simple, yet effective, and well-controlled mechanism to apply physiologically relevant homogenous mechanical equiaxial strain on three-dimensional cell-embedded tissue scaffolds. The design of EQUicycler ensured elimination of gripping effects through the use of biologically compatible silicone posts for direct transfer of the mechanical load to the scaffolds. Finite Element Modeling (FEM) was created to understand and to quantify how much applied global strain was transferred from the loading mechanism to the tissue constructs. In vitro studies were conducted on various cell lines associated with tissues exposed to equiaxial mechanical loading in their native environment. In vitro results demonstrated that EQUicycler was effective in maintaining and promoting the viability of different musculoskeletal cell lines and upregulating early differentiation of osteoprogenitor cells. By utilizing EQUicycler, collagen fibers of the constructs were actively remodeled. Residing cells within the collagen construct elongated and aligned with strain direction upon mechanical loading. EQUicycler can provide an efficient and cost-effective tool to conduct mechanistic studies for tissue engineered constructs designed for tissue systems under mechanical loading in vivo.

scholarly journals Cellular mechanisms regulating protein synthesis and skeletal muscle hypertrophy in animals

2009 ◽  
Vol 106 (4) ◽  
pp. 1367-1373 ◽  
Author(s):  
Mitsunori Miyazaki ◽  
Karyn A. Esser
Keyword(s):  
Skeletal Muscle ◽  
Cell Culture ◽  
Protein Synthesis ◽  
Mechanical Loading ◽  
Muscle Hypertrophy ◽  
Mammalian Target Of Rapamycin ◽  
Cellular Mechanisms ◽  
Skeletal Muscle Hypertrophy

Growth and maintenance of skeletal muscle mass is critical for long-term health and quality of life. Skeletal muscle is a highly adaptable tissue with well-known sensitivities to environmental cues such as growth factors, cytokines, nutrients, and mechanical loading. All of these factors act at the level of the cell and signal through pathways that lead to changes in phenotype through multiple mechanisms. In this review, we discuss the animal and cell culture models used and the signaling mechanisms identified in understanding regulation of protein synthesis in response to mechanical loading/resistance exercise. Particular emphasis has been placed on 1) alterations in mechanical loading and regulation of protein synthesis in both in vivo animal studies and in vitro cell culture studies and 2) upstream mediators regulating mammalian target of rapamycin signaling and protein synthesis during skeletal muscle hypertrophy.

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