8 results on '"Murphy, Meghan K."'
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2. TGF-β1, GDF-5, and BMP-2 stimulation induces chondrogenesis in expanded human articular chondrocytes and marrow-derived stromal cells.
- Author
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Murphy, Meghan K, Huey, Daniel J, Hu, Jerry C, and Athanasiou, Kyriacos A
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Cartilage ,Articular ,Bone Marrow Cells ,Chondrocytes ,Stromal Cells ,Humans ,Tissue Engineering ,Cell Differentiation ,Chondrogenesis ,Adult ,Male ,Transforming Growth Factor beta1 ,Bone Morphogenetic Protein 2 ,Growth Differentiation Factor 5 ,Adult stem cells ,Arthritis ,Differentiation ,Mesenchymal stem cells ,Tissue regeneration ,Immunology ,Biological Sciences ,Technology ,Medical and Health Sciences - Abstract
Replacement of degenerated cartilage with cell-based cartilage products may offer a long-term solution to halt arthritis' degenerative progression. Chondrocytes are frequently used in cell-based FDA-approved cartilage products; yet human marrow-derived stromal cells (hMSCs) show significant translational potential, reducing donor site morbidity and maintaining their undifferentiated phenotype with expansion. This study sought to investigate the effects of transforming growth factor β1 (TGF-β1), growth/differentiation factor 5 (GDF-5), and bone morphogenetic protein 2 (BMP-2) during postexpansion chondrogenesis in human articular chondrocytes (hACs) and to compare chondrogenesis in passaged hACs with that of passaged hMSCs. Through serial expansion, chondrocytes dedifferentiated, decreasing expression of chondrogenic genes while increasing expression of fibroblastic genes. However, following expansion, 10 ng/mL TGF-β1, 100 ng/mL GDF-5, or 100 ng/mL BMP-2 supplementation during three-dimensional aggregate culture each upregulated one or more markers of chondrogenic gene expression in both hACs and hMSCs. Additionally, in both cell types, the combination of TGF-β1, GDF-5, and BMP-2 induced the greatest upregulation of chondrogenic genes, that is, Col2A1, Col2A1/Col1A1 ratio, SOX9, and ACAN, and synthesis of cartilage-specific matrix, that is, glycosaminoglycans (GAGs) and ratio of collagen II/I. Finally, TGF-β1, GDF-5, and BMP-2 stimulation yielded mechanically robust cartilage rich in collagen II and GAGs in both cell types, following 4 weeks maturation. This study illustrates notable success in using the self-assembling method to generate robust, scaffold-free neocartilage constructs using expanded hACs and hMSCs.
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- 2015
3. Neocartilage integration in temporomandibular joint discs: physical and enzymatic methods
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Murphy, Meghan K, Arzi, Boaz, Prouty, Shannon M, Hu, Jerry C, and Athanasiou, Kyriacos A
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Engineering ,Biomedical Engineering ,Bioengineering ,Chronic Pain ,Dental/Oral and Craniofacial Disease ,Arthritis ,Pain Research ,Temporomandibular Muscle/Joint Disorder (TMJD) ,Musculoskeletal ,Animals ,Fibrocartilage ,Hyaline Cartilage ,Protein-Lysine 6-Oxidase ,Sus scrofa ,Temporomandibular Joint Disc ,Temporomandibular Joint Disorders ,Tensile Strength ,temporomandibular joint disc perforation ,lysyl oxidase ,suture ,cyanoacrylate ,mosaicplasty ,porcine ,General Science & Technology - Abstract
Integration of engineered musculoskeletal tissues with adjacent native tissues presents a significant challenge to the field. Specifically, the avascularity and low cellularity of cartilage elicit the need for additional efforts in improving integration of neocartilage within native cartilage. Self-assembled neocartilage holds significant potential in replacing degenerated cartilage, though its stabilization and integration in native cartilage require further efforts. Physical and enzymatic stabilization methods were investigated in an in vitro model for temporomandibular joint (TMJ) disc degeneration. First, in phase 1, suture, glue and press-fit constructs were compared in TMJ disc intermediate zone defects. In phase 1, suturing enhanced interfacial shear stiffness and strength immediately; after four weeks, a 15-fold increase in stiffness and a ninefold increase in strength persisted over press-fit. Neither suture nor glue significantly altered neocartilage properties. In phase 2, the effects of the enzymatic stabilization regimen composed of lysyl oxidase, CuSO4 and hydroxylysine were investigated. A full factorial design was employed, carrying forward the best physical method from phase 1, suturing. Enzymatic stabilization significantly increased interfacial shear stiffness after eight weeks. Combined enzymatic stabilization and suturing led to a fourfold increase in shear stiffness and threefold increase in strength over press-fit. Histological analysis confirmed the presence of a collagen-rich interface. Enzymatic treatment additionally enhanced neocartilage mechanical properties, yielding a tensile modulus over 6 MPa and compressive instantaneous modulus over 1200 kPa at eight weeks. Suturing enhances stabilization of neocartilage, and enzymatic treatment enhances functional properties and integration of neocartilage in the TMJ disc. Methods developed here are applicable to other orthopaedic soft tissues, including knee meniscus and hyaline articular cartilage.
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- 2015
4. Engineering a Fibrocartilage Spectrum through Modulation of Aggregate Redifferentiation
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Murphy, Meghan K, Masters, Taylor E, Hu, Jerry C, and Athanasiou, Kyriacos A
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Biological Sciences ,Animals ,Cell Culture Techniques ,Cell Differentiation ,Cell Proliferation ,Cell Survival ,Cells ,Cultured ,Chondrocytes ,Collagen ,Elastic Modulus ,Enzyme-Linked Immunosorbent Assay ,Female ,Fibrocartilage ,Glycosaminoglycans ,Swine ,Tensile Strength ,Tissue Engineering ,Costal chondrocytes ,Mono layer expansion ,Three-dimensional culture ,Self-Assembly ,Hyaline cartilage ,Technology ,Medical and Health Sciences ,Neurology & Neurosurgery ,Biological sciences - Abstract
Expanded costochondral cells provide a clinically relevant cell source for engineering both fibrous and hyaline articular cartilage. Expanding chondrocytes in a monolayer results in a shift toward a proliferative, fibroblastic phenotype. Three-dimensional aggregate culture may, however, be used to recover chondrogenic matrix production. This study sought to engineer a spectrum of fibrous to hyaline neocartilage from a single cell source by varying the duration of three-dimensional culture following expansion. In third passage porcine costochondral cells, the effects of aggregate culture duration were assessed after 0, 8, 11, 14, and 21 days of aggregate culture and after 4 subsequent weeks of neocartilage formation. Varying the duration of aggregate redifferentiation generated a spectrum of fibrous to hyaline neocartilage. Within 8 days of aggregation, proliferation ceased, and collagen and glycosaminoglycan production increased, compared with monolayer cells. In self-assembled neocartilage, type II-to-I collagen ratio increased with increasing aggregate duration, yet glycosaminoglycan content varied minimally. Notably, 14 days of aggregate redifferentiation increased collagen content by 25%, tensile modulus by over 110%, and compressive moduli by over 50%, compared with tissue formed in the absence of redifferentiation. A spectrum of fibrous to hyaline cartilage was generated using a single, clinically relevant cell source, improving the translational potential of engineered cartilage.
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- 2015
5. Inducing articular cartilage phenotype in costochondral cells
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Murphy, Meghan K, DuRaine, Grayson D, Reddi, A, Hu, Jerry C, and Athanasiou, Kyriacos A
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Abstract Introduction Costochondral cells may be isolated with minimal donor site morbidity and are unaffected by pathologies of the diarthrodial joints. Identification of optimal exogenous stimuli will allow abundant and robust hyaline articular cartilage to be formed from this cell source. Methods In a three factor, two level full factorial design, the effects of hydrostatic pressure (HP), transforming growth factor β1 (TGF-β1), and chondroitinase ABC (C-ABC), and all resulting combinations, were assessed in third passage expanded, redifferentiated costochondral cells. After 4 wks, the new cartilage was assessed for matrix content, superficial zone protein (SZP), and mechanical properties. Results Hyaline articular cartilage was generated, demonstrating the presence of type II collagen and SZP, and the absence of type I collagen. TGF-β1 upregulated collagen synthesis by 175% and glycosaminoglycan synthesis by 75%, resulting in a nearly 200% increase in tensile and compressive moduli. C-ABC significantly increased collagen content, and fibril density and diameter, leading to a 125% increase in tensile modulus. Hydrostatic pressure increased fibril diameter by 30% and tensile modulus by 45%. Combining TGF-β1 with C-ABC synergistically increased collagen content by 300% and tensile strength by 320%, over control. No significant differences were observed between C-ABC/TGF-β1 dual treatment and HP/C-ABC/TGF-β1. Conclusions Employing biochemical, biophysical, and mechanical stimuli generated robust hyaline articular cartilage with a tensile modulus of 2 MPa and a compressive instantaneous modulus of 650 kPa. Using expanded, redifferentiated costochondral cells in the self-assembling process allows for recapitulation of robust mechanical properties, and induced SZP expression, key characteristics of functional articular cartilage.
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- 2013
6. Enhancing post-expansion chondrogenic potential of costochondral cells in self-assembled neocartilage.
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Murphy, Meghan K, Huey, Daniel J, Reimer, Andrew J, Hu, Jerry C, and Athanasiou, Kyriacos A
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Cartilage ,Articular ,Chondrocytes ,Animals ,Swine ,Collagen Type II ,Glycosaminoglycans ,Cell Culture Techniques ,Tissue Engineering ,Cell Differentiation ,Cell Proliferation ,Chondrogenesis ,Biomechanical Phenomena ,Cartilage ,Articular ,Bioengineering ,Musculoskeletal ,General Science & Technology - Abstract
The insufficient healing capacity of articular cartilage necessitates mechanically functional biologic tissue replacements. Using cells to form biomimetic cartilage implants is met with the challenges of cell scarcity and donor site morbidity, requiring expanded cells that possess the ability to generate robust neocartilage. To address this, this study assesses the effects of expansion medium supplementation (bFGF, TFP, FBS) and self-assembled construct seeding density (2, 3, 4 million cells/5 mm dia. construct) on the ability of costochondral cells to generate biochemically and biomechanically robust neocartilage. Results show TFP (1 ng/mL TGF-β1, 5 ng/mL bFGF, 10 ng/mL PDGF) supplementation of serum-free chondrogenic expansion medium enhances the post-expansion chondrogenic potential of costochondral cells, evidenced by increased glycosaminoglycan content, decreased type I/II collagen ratio, and enhanced compressive properties. Low density (2 million cells/construct) enhances matrix synthesis and tensile and compressive mechanical properties. Combined, TFP and Low density interact to further enhance construct properties. That is, with TFP, Low density increases type II collagen content by over 100%, tensile stiffness by over 300%, and compressive moduli by over 140%, compared with High density. In conclusion, the interaction of TFP and Low density seeding enhances construct material properties, allowing for a mechanically functional, biomimetic cartilage to be formed using clinically relevant costochondral cells.
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- 2013
7. Temporomandibular Disorders: A Review of Etiology, Clinical Management, and Tissue Engineering Strategies.
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Murphy, Meghan K., MacBarb, Regina F., Wong, Mark E., and Athanasiou, Kyriacos A.
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TISSUE engineering ,MUSCULOSKELETAL system diseases ,TEMPOROMANDIBULAR disorders ,THERAPEUTICS - Abstract
The article presents a study on the etiology, clinical management and tissue engineering strategies for treating temporomandibular disorders (TMD). It offers information on TMD, a system for classifying the progression of internal derangement and characterization of temporomandibular joints, and factors that may play a role in the progression of TMD and the associated degenerative changes.
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- 2013
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8. Temporomandibular Disorders: A Review of Etiology, Clinical Management, and Tissue Engineering Strategies.
- Author
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Murphy, Meghan K., MacBarb, Regina F., Wong, Mark E., and Athanasiou, Kyriacos A.
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TEMPOROMANDIBULAR disorders ,STOMATOGNATHIC system diseases ,CARTILAGE ,TISSUE engineering ,REGENERATIVE medicine - Abstract
Temporomandibular disorders (TMD) are a class of degenerative musculoskeletal conditions associated with morphologic and functional deformities that affect up to 25% of the population, but their etiology and progression are poorly understood and, as a result, treatment options are limited. In up to 70% of cases, TMD are accompanied by malpositioning of the temporomandibular joint (TMJ) disc, termed "internal derangement." Although the onset is not well characterized, correlations between internal derangement and osteoarthritic change have been identified. Because of the complex and unique nature of each TMD case, diagnosis requires patient-specific analysis accompanied by various diagnostic modalities. Likewise, treatment requires customized plans to address the specific characteristics of each patient's disease. In the mechanically demanding and biochemically active environment of the TMJ, therapeutic approaches that can restore joint functionality while responding to changes in the joint have become a necessity. One such approach, tissue engineering, which may be capable of integration and adaptation in the TMJ, carries significant potential for the development of repair and replacement tissues. The following review presents a synopsis of etiology, current treatment methods, and the future of tissue engineering for repairing and/or replacing diseased joint components, specifically the mandibular condyle and TMJ disc. An analysis of native tissue characterization to assist clinicians in identifying tissue engineering objectives and validation metrics for restoring healthy and functional structures of the TMJ is followed by a discussion of current trends in tissue engineering. [ABSTRACT FROM AUTHOR]
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- 2011
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