Effect of passage number of genetically modified TGF-β3 expressing primary chondrocytes on the chondrogenesis of ATDC5 cells in a 3D coculture system

2022 ◽  
Author(s):  
Ke Chen ◽  
Hanzheng Chen ◽  
Hui Gao ◽  
Wei Zhou ◽  
Shicong Zheng ◽  
...  
Keyword(s):  
Tissue Engineering ◽  
Transfection Efficiency ◽  
Genetically Modified ◽  
Cartilage Tissue Engineering ◽  
Cartilage Regeneration ◽  
Cartilage Tissue ◽  
Coculture System ◽  
Effective Combination ◽  
Passage Number ◽  
Potential Strategy

Abstract Due to the lack of blood vessels, nerves and lymphatics, articular cartilage is difficult to repair once damaged. Tissue engineering is considered to be a potential strategy for cartilage regeneration. Successful tissue engineering strategies depend on the effective combination of biomaterials, seed cells and biological factors. In our previous study, a genetically modified coculture system with chondrocytes and ATDC5 cells in an alginate hydrogel has exhibited a superior ability to enhance chondrogenesis. In this study, we further evaluated the influence of chondrocytes at various passages on chondrogenesis in the coculture system. The results demonstrated that transfection efficiency was hardly influenced by the passage of chondrocytes. The coculture system with passage 5 (P5) chondrocytes had a better effect on chondrogenesis of ATDC 5 cells, while chondrocytes in this coculture system presented higher levels of dedifferentiation than other groups with P1 or P3 chondrocytes. Therefore, P5 chondrocytes were shown to be more suitable for the coculture system, as they accumulated in sufficient cell numbers with more passages and had a higher level of dedifferentiation, which was prone to form a favorable niche for chondrogenesis of ATDC5 cells. This study may provide fresh insights for future cartilage tissue engineering strategies with a combination of a coculture system and advanced biomaterials.

scholarly journals Digital Light Processing Bioprinted Human Chondrocyte-Laden Poly (γ-Glutamic Acid)/Hyaluronic Acid Bio-Ink towards Cartilage Tissue Engineering

Biomedicines ◽  
2021 ◽  
Vol 9 (7) ◽  
pp. 714
Author(s):  
Alvin Kai-Xing Lee ◽  
Yen-Hong Lin ◽  
Chun-Hao Tsai ◽  
Wan-Ting Chang ◽  
Tsung-Li Lin ◽  
...  
Keyword(s):  
United States ◽  
Tissue Engineering ◽  
Hyaluronic Acid ◽  
Glutamic Acid ◽  
Cellular Proliferation ◽  
Cartilage Tissue Engineering ◽  
Cartilage Regeneration ◽  
The United States ◽  
Cartilage Injury ◽  
Cartilage Tissue

Cartilage injury is the main cause of disability in the United States, and it has been projected that cartilage injury caused by osteoarthritis will affect 30% of the entire United States population by the year 2030. In this study, we modified hyaluronic acid (HA) with γ-poly(glutamic) acid (γ-PGA), both of which are common biomaterials used in cartilage engineering, in an attempt to evaluate them for their potential in promoting cartilage regeneration. As seen from the results, γ-PGA-GMA and HA, with glycidyl methacrylate (GMA) as the photo-crosslinker, could be successfully fabricated while retaining the structural characteristics of γ-PGA and HA. In addition, the storage moduli and loss moduli of the hydrogels were consistent throughout the curing durations. However, it was noted that the modification enhanced the mechanical properties, the swelling equilibrium rate, and cellular proliferation, and significantly improved secretion of cartilage regeneration-related proteins such as glycosaminoglycan (GAG) and type II collagen (Col II). The cartilage tissue proof with Alcian blue further demonstrated that the modification of γ-PGA with HA exhibited suitability for cartilage tissue regeneration and displayed potential for future cartilage tissue engineering applications. This study built on the previous works involving HA and further showed that there are unlimited ways to modify various biomaterials in order to further bring cartilage tissue engineering to the next level.

scholarly journals Advanced Hydrogels for Cartilage Tissue Engineering: Recent Progress and Future Directions

Polymers ◽  
2021 ◽  
Vol 13 (23) ◽  
pp. 4199
Author(s):  
Mahshid Hafezi ◽  
Saied Nouri Khorasani ◽  
Mohadeseh Zare ◽  
Rasoul Esmaeely Neisiany ◽  
Pooya Davoodi
Keyword(s):  
Tissue Engineering ◽  
Cartilage Tissue Engineering ◽  
Cartilage Regeneration ◽  
Biomechanical Properties ◽  
Tissue Growth ◽  
Cartilage Tissue ◽  
Self Healing ◽  
Advantages And Disadvantages ◽  
Wide Range

Cartilage is a tension- and load-bearing tissue and has a limited capacity for intrinsic self-healing. While microfracture and arthroplasty are the conventional methods for cartilage repair, these methods are unable to completely heal the damaged tissue. The need to overcome the restrictions of these therapies for cartilage regeneration has expanded the field of cartilage tissue engineering (CTE), in which novel engineering and biological approaches are introduced to accelerate the development of new biomimetic cartilage to replace the injured tissue. Until now, a wide range of hydrogels and cell sources have been employed for CTE to either recapitulate microenvironmental cues during a new tissue growth or to compel the recovery of cartilaginous structures via manipulating biochemical and biomechanical properties of the original tissue. Towards modifying current cartilage treatments, advanced hydrogels have been designed and synthesized in recent years to improve network crosslinking and self-recovery of implanted scaffolds after damage in vivo. This review focused on the recent advances in CTE, especially self-healing hydrogels. The article firstly presents the cartilage tissue, its defects, and treatments. Subsequently, introduces CTE and summarizes the polymeric hydrogels and their advances. Furthermore, characterizations, the advantages, and disadvantages of advanced hydrogels such as multi-materials, IPNs, nanomaterials, and supramolecular are discussed. Afterward, the self-healing hydrogels in CTE, mechanisms, and the physical and chemical methods for the synthesis of such hydrogels for improving the reformation of CTE are introduced. The article then briefly describes the fabrication methods in CTE. Finally, this review presents a conclusion of prevalent challenges and future outlooks for self-healing hydrogels in CTE applications.

Methylsulfonylmethane-loaded electrospun poly(lactide-co-glycolide) mats for cartilage tissue engineering

RSC Advances ◽  
2015 ◽  
Vol 5 (117) ◽  
pp. 96725-96732 ◽  
Author(s):  
Zongliang Wang ◽  
Yu Wang ◽  
Peibiao Zhang ◽  
Xuesi Chen
Keyword(s):  
Tissue Engineering ◽  
Cartilage Tissue Engineering ◽  
Cartilage Regeneration ◽  
Cartilage Tissue ◽  
Promising Candidate

The electrospun MSM-loaded PLGA mat is a promising candidate for cartilage regeneration.

scholarly journals Chondrogenic Potential of Dental-Derived Mesenchymal Stromal Cells

Osteology ◽  
2021 ◽  
Vol 1 (3) ◽  
pp. 149-174
Author(s):  
Naveen Jeyaraman ◽  
Gollahalli Shivashankar Prajwal ◽  
Madhan Jeyaraman ◽  
Sathish Muthu ◽  
Manish Khanna
Keyword(s):  
Tissue Engineering ◽  
Mesenchymal Stromal Cells ◽  
Tissue Regeneration ◽  
Stromal Cells ◽  
Cartilage Tissue Engineering ◽  
Cartilage Regeneration ◽  
Cartilage Tissue ◽  
Dentin Matrix

The field of tissue engineering has revolutionized the world in organ and tissue regeneration. With the robust research among regenerative medicine experts and researchers, the plausibility of regenerating cartilage has come into the limelight. For cartilage tissue engineering, orthopedic surgeons and orthobiologists use the mesenchymal stromal cells (MSCs) of various origins along with the cytokines, growth factors, and scaffolds. The least utilized MSCs are of dental origin, which are the richest sources of stromal and progenitor cells. There is a paradigm shift towards the utilization of dental source MSCs in chondrogenesis and cartilage regeneration. Dental-derived MSCs possess similar phenotypes and genotypes like other sources of MSCs along with specific markers such as dentin matrix acidic phosphoprotein (DMP) -1, dentin sialophosphoprotein (DSPP), alkaline phosphatase (ALP), osteopontin (OPN), bone sialoprotein (BSP), and STRO-1. Concerning chondrogenicity, there is literature with marginal use of dental-derived MSCs. Various studies provide evidence for in-vitro and in-vivo chondrogenesis by dental-derived MSCs. With such evidence, clinical trials must be taken up to support or refute the evidence for regenerating cartilage tissues by dental-derived MSCs. This article highlights the significance of dental-derived MSCs for cartilage tissue regeneration.

scholarly journals The Application of Bioreactors for Cartilage Tissue Engineering: Advances, Limitations, and Future Perspectives

2021 ◽  
Vol 2021 ◽  
pp. 1-13
Author(s):  
Liwei Fu ◽  
Pinxue Li ◽  
Hao Li ◽  
Cangjian Gao ◽  
Zhen Yang ◽  
...  
Keyword(s):  
Tissue Engineering ◽  
Cell Culture ◽  
Articular Cartilage ◽  
Cartilage Tissue Engineering ◽  
Cartilage Regeneration ◽  
Cartilage Tissue ◽  
Future Perspectives ◽  
Mechanical Environment ◽  
Biomechanical Stimuli ◽  
Articular Cartilage Regeneration

Tissue engineering (TE) has brought new hope for articular cartilage regeneration, as TE can provide structural and functional substitutes for native tissues. The basic elements of TE involve scaffolds, seeded cells, and biochemical and biomechanical stimuli. However, there are some limitations of TE; what most important is that static cell culture on scaffolds cannot simulate the physiological environment required for the development of natural cartilage. Recently, bioreactors have been used to simulate the physical and mechanical environment during the development of articular cartilage. This review aims to provide an overview of the concepts, categories, and applications of bioreactors for cartilage TE with emphasis on the design of various bioreactor systems.

scholarly journals Adipose-Derived Mesenchymal Stem Cell Chondrospheroids Cultured in Hypoxia and a 3D Porous Chitosan/Chitin Nanocrystal Scaffold as a Platform for Cartilage Tissue Engineering

2020 ◽  
Vol 21 (3) ◽  
pp. 1004 ◽  
Author(s):  
Veronica Zubillaga ◽  
Ana Alonso-Varona ◽  
Susana C. M. Fernandes ◽  
Asier M. Salaberria ◽  
Teodoro Palomares
Keyword(s):  
Tissue Engineering ◽  
Articular Cartilage ◽  
Collagen Type ◽  
Porous Scaffold ◽  
Cartilage Tissue Engineering ◽  
Cartilage Regeneration ◽  
Cartilage Tissue ◽  
Type I ◽  
Low Oxygen ◽  
Porous Chitosan

Articular cartilage degeneration is one of the most common causes of pain and disability in middle-aged and older people. Tissue engineering (TE) has shown great therapeutic promise for this condition. The design of cartilage regeneration constructs must take into account the specific characteristics of the cartilaginous matrix, as well as the avascular nature of cartilage and its cells’ peculiar arrangement in isogenic groups. Keeping these factors in mind, we have designed a 3D porous scaffold based on genipin-crosslinked chitosan/chitin nanocrystals for spheroid chondral differentiation of human adipose tissue-derived mesenchymal stem cells (hASCs) induced in hypoxic conditions. First, we demonstrated that, under low oxygen conditions, the chondrospheroids obtained express cartilage-specific markers including collagen type II (COL2A1) and aggrecan, lacking expression of osteogenic differentiation marker collagen type I (COL1A2). These results were associated with an increased expression of hypoxia-inducible factor 1α, which positively directs COL2A1 and aggrecan expression. Finally, we determined the most suitable chondrogenic differentiation pattern when hASC spheroids were seeded in the 3D porous scaffold under hypoxia and obtained a chondral extracellular matrix with a high sulphated glycosaminoglycan content, which is characteristic of articular cartilage. These findings highlight the potential use of such templates in cartilage tissue engineering.

New strategies for cartilage regeneration exploiting selected glycosaminoglycans to enhance cell fate determination

2014 ◽  
Vol 42 (3) ◽  
pp. 703-709 ◽  
Author(s):  
Bethanie I. Ayerst ◽  
Anthony J. Day ◽  
Victor Nurcombe ◽  
Simon M. Cool ◽  
Catherine L.R. Merry
Keyword(s):  
Tissue Engineering ◽  
Cell Fate ◽  
Cartilage Tissue Engineering ◽  
Cartilage Regeneration ◽  
Stem Cell Differentiation ◽  
Biologically Active ◽  
Cartilage Tissue ◽  
Research Strategies ◽  
Tissue Engineering Scaffolds ◽  
Ecm Extracellular Matrix

Most research strategies for cartilage tissue engineering use extended culture with complex media loaded with costly GFs (growth factors) to drive tissue assembly and yet they result in the production of cartilage with inferior mechanical and structural properties compared with the natural tissue. Recent evidence suggests that GAGs (glycosaminoglycans) incorporated into tissue engineering scaffolds can sequester and/or activate GFs and thereby more effectively mimic the natural ECM (extracellular matrix). Such approaches may have potential for the improvement of cartilage engineering. However, natural GAGs are structurally complex and heterogeneous, making structure–function relationships hard to determine and clinical translation difficult. Importantly, subfractions of GAGs with specific chain lengths and sulfation patterns have been shown to activate key signalling processes during stem cell differentiation. In addition, recently, GAGs have been bound to synthetic biomaterials, such as electrospun scaffolds and hydrogels, in biologically active conformations, and methods to purify and select affinity-matched GAGs for specific GFs have also been developed. The identification and use of specific GAG moieties to promote chondrogenesis is therefore an exciting new avenue of research. Combining these with synthetic biomaterials may allow a more effective mimicry of the natural ECM, reduction in the need for expensive GFs, and perhaps the deposition of an articular cartilage-like matrix in a clinically relevant manner.

scholarly journals Harnessing Biomechanics to Develop Cartilage Regeneration Strategies

2015 ◽  
Vol 137 (2) ◽  
Author(s):  
Kyriacos A. Athanasiou ◽  
Donald J. Responte ◽  
Wendy E. Brown ◽  
Jerry C. Hu
Keyword(s):  
Tissue Engineering ◽  
Articular Cartilage ◽  
Biochemical Characterization ◽  
Articular Chondrocytes ◽  
Lysyl Oxidase ◽  
Cartilage Tissue Engineering ◽  
Cartilage Regeneration ◽  
Cartilage Tissue ◽  
Main Function ◽  
Mechanical Stimuli

As this review was prepared specifically for the American Society of Mechanical Engineers H.R. Lissner Medal, it primarily discusses work toward cartilage regeneration performed in Dr. Kyriacos A. Athanasiou's laboratory over the past 25 years. The prevalence and severity of degeneration of articular cartilage, a tissue whose main function is largely biomechanical, have motivated the development of cartilage tissue engineering approaches informed by biomechanics. This article provides a review of important steps toward regeneration of articular cartilage with suitable biomechanical properties. As a first step, biomechanical and biochemical characterization studies at the tissue level were used to provide design criteria for engineering neotissues. Extending this work to the single cell and subcellular levels has helped to develop biochemical and mechanical stimuli for tissue engineering studies. This strong mechanobiological foundation guided studies on regenerating hyaline articular cartilage, the knee meniscus, and temporomandibular joint (TMJ) fibrocartilage. Initial tissue engineering efforts centered on developing biodegradable scaffolds for cartilage regeneration. After many years of studying scaffold-based cartilage engineering, scaffoldless approaches were developed to address deficiencies of scaffold-based systems, resulting in the self-assembling process. This process was further improved by employing exogenous stimuli, such as hydrostatic pressure, growth factors, and matrix-modifying and catabolic agents, both singly and in synergistic combination to enhance neocartilage functional properties. Due to the high cell needs for tissue engineering and the limited supply of native articular chondrocytes, costochondral cells are emerging as a suitable cell source. Looking forward, additional cell sources are investigated to render these technologies more translatable. For example, dermis isolated adult stem (DIAS) cells show potential as a source of chondrogenic cells. The challenging problem of enhanced integration of engineered cartilage with native cartilage is approached with both familiar and novel methods, such as lysyl oxidase (LOX). These diverse tissue engineering strategies all aim to build upon thorough biomechanical characterizations to produce functional neotissue that ultimately will help combat the pressing problem of cartilage degeneration. As our prior research is reviewed, we look to establish new pathways to comprehensively and effectively address the complex problems of musculoskeletal cartilage regeneration.

scholarly journals Biomimetic hydrogels designed for cartilage tissue engineering

2021 ◽  
Author(s):  
Kresanti D. Ngadimin ◽  
Alexander Stokes ◽  
Piergiorgio Gentile ◽  
Ana M. Ferreira
Keyword(s):  
Tissue Engineering ◽  
Hyaluronic Acid ◽  
Polyethylene Glycol ◽  
Chondroitin Sulfate ◽  
Cartilage Tissue Engineering ◽  
Cartilage Regeneration ◽  
Cartilage Tissue

Cartilage-like hydrogels based on materials like gelatin, chondroitin sulfate, hyaluronic acid and polyethylene glycol are reviewed and contrasted, revealing existing limitations and challenges on biomimetic hydrogels for cartilage regeneration.

scholarly journals Applications of Hydrogel with Special Physical Properties in Bone and Cartilage Regeneration

Materials ◽  
2021 ◽  
Vol 14 (1) ◽  
pp. 235
Author(s):  
Hua Lin ◽  
Cuilan Yin ◽  
Anchun Mo ◽  
Guang Hong
Keyword(s):  
Tissue Engineering ◽  
Physical Properties ◽  
Cartilage Tissue Engineering ◽  
Antibacterial Properties ◽  
High Strength ◽  
Cartilage Regeneration ◽  
Cartilage Tissue ◽  
Medical Progress ◽  
Extracellular Matrix Components ◽  
And Cartilage

Hydrogel is a polymer matrix containing a large amount of water. It is similar to extracellular matrix components. It comes into contact with blood, body fluids, and human tissues without affecting the metabolism of organisms. It can be applied to bone and cartilage tissues. This article introduces the high-strength polymer hydrogel and its modification methods to adapt to the field of bone and cartilage tissue engineering. From the perspective of the mechanical properties of hydrogels, the mechanical strength of hydrogels has experienced from the weak-strength traditional hydrogels to the high-strength hydrogels, then the injectable hydrogels were invented and realized the purpose of good fluidity before the use of hydrogels and high strength in the later period. In addition, specific methods to give special physical properties to the hydrogel used in the field of bone and cartilage tissue engineering will also be discussed, such as 3D printing, integrated repair of bone and cartilage tissue, bone vascularization, and osteogenesis hydrogels that regulate cell growth, antibacterial properties, and repeatable viscosity in humid environments. Finally, we explain the main reasons and contradictions in current applications, look forward to the research prospects in the field of bone and cartilage tissue engineering, and emphasize the importance of conducting research in this field to promote medical progress.

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