Your search keyword '"Le W. Huwe"' showing total 3 results

1. Tissue engineering toward temporomandibular joint disc regeneration

Author

Mark E. Wong, Boaz Arzi, Meghan K. Houghton, Le W. Huwe, Jerry C. Hu, Natalia Vapniarsky, Kyriacos A. Athanasiou, David C. Hatcher, and James W. Wilson

Subjects

Swine, Dentistry, 02 engineering and technology, Osteoarthritis, Regenerative Medicine, Medical and Health Sciences, Imaging, 0302 clinical medicine, Implants, Experimental, Tissue engineering, Temporomandibular Joint Disc, Medicine, Miniature, Pain Research, General Medicine, Biological Sciences, Allografts, medicine.anatomical_structure, Swine, Miniature, Chronic Pain, Development of treatments and therapeutic interventions, 0206 medical engineering, Perforation (oil well), Bioengineering, Article, Experimental, 03 medical and health sciences, Defect closure, Imaging, Three-Dimensional, Chondrocytes, Immune Tolerance, Animals, Regeneration, Implants, Dental/Oral and Craniofacial Disease, Temporomandibular Muscle/Joint Disorder (TMJD), 5.2 Cellular and gene therapies, Tissue Engineering, business.industry, Arthritis, Regeneration (biology), 030206 dentistry, medicine.disease, 020601 biomedical engineering, Temporomandibular joint, Repair tissue, Musculoskeletal, Three-Dimensional, business

Abstract

© 2018 The Authors, some Rights Reserved. Treatments for temporomandibular joint (TMJ) disc thinning and perforation, conditions prevalent in TMJ pathologies, are palliative but not reparative. To address this, scaffold-free tissue-engineered implants were created using allogeneic, passaged costal chondrocytes. A combination of compressive and bioactive stimulation regimens produced implants with mechanical properties akin to those of the native disc. Efficacy in repairing disc thinning was examined in minipigs. Compared to empty controls, treatment with tissue-engineered implants restored disc integrity by inducing 4.4 times more complete defect closure, formed 3.4-fold stiffer repair tissue, and promoted 3.2-fold stiffer intralaminar fusion. The osteoarthritis score (indicative of degenerative changes) of the untreated group was 3.0-fold of the implant-treated group. This tissue engineering strategy paves the way for developing tissue-engineered implants as clinical treatments for TMJ disc thinning.

Published

2018

2. Characterization of costal cartilage and its suitability as a cell source for articular cartilage tissue engineering

Author

Le W. Huwe, Wendy E. Brown, Jerry C. Hu, and Kyriacos A. Athanasiou

Subjects

0301 basic medicine, musculoskeletal diseases, Cartilage, Articular, patellofemoral cartilage, Clinical Sciences, Medical Physiology, Biomedical Engineering, Medicine (miscellaneous), Articular cartilage, cartilage tissue engineering, Cartilage tissue engineering, Condyle, Chondrocyte, Article, Biomaterials, 03 medical and health sciences, 0302 clinical medicine, Tissue engineering, Tensile Strength, medicine, Animals, 030203 arthritis & rheumatology, Sheep, Tissue Engineering, Chemistry, Cartilage, Regeneration (biology), cartilage mechanical properties, Costal cartilage, musculoskeletal system, Biomechanical Phenomena, Costal Cartilage, 030104 developmental biology, medicine.anatomical_structure, articular cartilage regeneration, alternative cell source, costal cartilage characterization, Biomedical engineering, Articular

Abstract

Costal cartilage is a promising donor source of chondrocytes to alleviate cell scarcity in articular cartilage tissue engineering. Limited knowledge exists, however, on costal cartilage characteristics. This study describes the characterization of costal cartilage and articular cartilage properties and compares neocartilage engineered with costal chondrocytes to native articular cartilage, all within a sheep model. Specifically, we (a) quantitatively characterized the properties of costal cartilage in comparison to patellofemoral articular cartilage, and (b) evaluated the quality of neocartilage derived from costal chondrocytes for potential use in articular cartilage regeneration. Ovine costal and articular cartilages from various topographical locations were characterized mechanically, biochemically, and histologically. Costal cartilage was stiffer in compression but softer and weaker in tension than articular cartilage. These differences were attributed to high amounts of glycosaminoglycans and mineralization and a low amount of collagen in costal cartilage. Compared to articular cartilage, costal cartilage was more densely populated with chondrocytes, rendering it an excellent chondrocyte source. In terms of tissue engineering, using the self-assembling process, costal chondrocytes formed articular cartilage-like neocartilage. Quantitatively compared via a functionality index, neocartilage achieved 55% of the medial condyle cartilage mechanical and biochemical properties. This characterization study highlighted the differences between costal and articular cartilages in native forms and demonstrated that costal cartilage is a valuable source of chondrocytes suitable for articular cartilage regeneration strategies.

Published

2018

3. Tension stimulation drives tissue formation in scaffold-free systems

Author

Kyriacos A. Athanasiou, Jerry C. Hu, Courtney Gegg, Jennifer K. Lee, Le W. Huwe, Ashkan Aryaei, and Nikolaos K. Paschos

Subjects

0301 basic medicine, Cartilage, Articular, Male, Scaffold, Materials science, 0206 medical engineering, Nude, Mice, Nude, Stimulation, 02 engineering and technology, Matrix (biology), Article, 03 medical and health sciences, Mice, Chondrocytes, Tissue engineering, Tensile Strength, Ultimate tensile strength, medicine, Animals, Humans, General Materials Science, Tissue formation, Nanoscience & Nanotechnology, Tissue Engineering, Tension (physics), Mechanical Engineering, Cartilage, General Chemistry, Condensed Matter Physics, 020601 biomedical engineering, 030104 developmental biology, medicine.anatomical_structure, Mechanics of Materials, Biophysics, Cattle, Articular

Abstract

Scaffold-free systems have emerged as viable approaches for engineering load-bearing tissues. However, the tensile properties of engineered tissues have remained far below the values for native tissue. Here, by using self-assembled articular cartilage as a model to examine the effects of intermittent and continuous tension stimulation on tissue formation, we show that the application of tension alone, or in combination with matrix remodelling and synthesis agents, leads to neocartilage with tensile properties approaching those of native tissue. Implantation of tension-stimulated tissues results in neotissues that are morphologically reminiscent of native cartilage. We also show that tension stimulation can be translated to a human cell source to generate anisotropic human neocartilage with enhanced tensile properties. Tension stimulation, which results in nearly sixfold improvements in tensile properties over unstimulated controls, may allow the engineering of mechanically robust biological replacements of native tissue.

Published

2017