Your search keyword '"Kensuke, Ikuta"' showing total 3 results

1. In Vitro Maturation and In Vivo Integration and Function of an Engineered Cell-Seeded Disc-like Angle Ply Structure (DAPS) for Total Disc Arthroplasty

Author

Beth G. Ashinsky, Kensuke Ikuta, Robert L. Mauck, John T. Martin, Dae-Hyeong Kim, Sarah E. Gullbrand, Dawn M. Elliott, Harvey E. Smith, Lachlan J. Smith, and Christian Pfeifer

Subjects

Male, 0301 basic medicine, Total Disc Replacement, Total disc replacement, Cell, Bony fusion, lcsh:Medicine, 02 engineering and technology, Article, Prosthesis Implantation, 03 medical and health sciences, Subcutaneous Tissue, In vivo, medicine, Animals, lcsh:Science, Cells, Cultured, Multidisciplinary, Tissue Engineering, biology, Chemistry, lcsh:R, Total Disc Arthroplasty, Anatomy, 021001 nanoscience & nanotechnology, Rats, In vitro maturation, 030104 developmental biology, medicine.anatomical_structure, Proteoglycan, biology.protein, Cattle, lcsh:Q, 0210 nano-technology, Function (biology), Biomedical engineering

Abstract

Total disc replacement with an engineered substitute is a promising avenue for treating advanced intervertebral disc disease. Toward this goal, we developed cell-seeded disc-like angle ply structures (DAPS) and showed through in vitro studies that these constructs mature to match native disc composition, structure, and function with long-term culture. We then evaluated DAPS performance in an in vivo rat model of total disc replacement; over 5 weeks in vivo, DAPS maintained their structure, prevented intervertebral bony fusion, and matched native disc mechanical function at physiologic loads in situ. However, DAPS rapidly lost proteoglycan post-implantation and did not integrate into adjacent vertebrae. To address this, we modified the design to include polymer endplates to interface the DAPS with adjacent vertebrae, and showed that this modification mitigated in vivo proteoglycan loss while maintaining mechanical function and promoting integration. Together, these data demonstrate that cell-seeded engineered discs can replicate many characteristics of the native disc and are a viable option for total disc arthroplasty.

Published

2017

2. *Optimization of Preculture Conditions to Maximize the In Vivo Performance of Cell-Seeded Engineered Intervertebral Discs

Author

Robert L. Mauck, Dong Hwa Kim, Dawn M. Elliott, John T. Martin, Beth G. Ashinsky, B. Mohanraj, Lachlan J. Smith, Kensuke Ikuta, Harvey E. Smith, and Sarah E. Gullbrand

Subjects

Chemistry, 0206 medical engineering, Biomedical Engineering, Bioengineering, Intervertebral disc, 02 engineering and technology, Matrix (biology), 021001 nanoscience & nanotechnology, 020601 biomedical engineering, Biochemistry, Special Focus Articles, In vitro, Cell biology, Biomaterials, Glycosaminoglycan, Chemically defined medium, medicine.anatomical_structure, Tissue engineering, Transforming growth factor, beta 3, In vivo, medicine, 0210 nano-technology, Biomedical engineering

Abstract

The development of engineered tissues has progressed over the past 20 years from in vitro characterization to in vivo implementation. For musculoskeletal tissue engineering in particular, the emphasis of many of these studies was to select conditions that maximized functional and compositional gains in vitro. However, the transition from the favorable in vitro culture environment to a less favorable in vivo environment has proven difficult, and, in many cases, engineered tissues do not retain their preimplantation phenotype after even short periods in vivo. Our laboratory recently developed disc-like angle-ply structures (DAPS), an engineered intervertebral disc for total disc replacement. In this study, we tested six different preculture media formulations (three serum-containing and three chemically defined, with varying doses of transforming growth factor β3 [TGF-β3] and varying strategies to introduce serum) for their ability to preserve DAPS composition and metabolic activity during the transition from in vitro culture to in vivo implantation in a subcutaneous athymic rat model. We assayed implants before and after implantation to determine collagen content, glycosaminoglycan (GAG) content, metabolic activity, and magnetic resonance imaging (MRI) characteristics. A chemically defined media condition that incorporated TGF-β3 promoted the deposition of GAG and collagen in DAPS in vitro, the maintenance of accumulated matrix in vivo, and minimal changes in the metabolic activity of cells within the construct. Preculture in serum-containing media (with or without TGF-β3) was not compatible with DAPS maturation, particularly in the nucleus pulposus (NP) region. All groups showed increased collagen production after implantation. These findings define a favorable preculture strategy for the translation of engineered discs seeded with disc cells.

Published

2017

3. A radiopaque electrospun scaffold for engineering fibrous musculoskeletal tissues: Scaffold characterization and in vivo applications

Author

Robert L. Mauck, Kensuke Ikuta, Christian Pfeifer, John T. Martin, Dawn M. Elliott, Subash Poudel, Andrew H. Milby, and Harvey E. Smith

Subjects

Scaffold, Materials science, Rotation, Radiodensity, Joint Prosthesis, Biomedical Engineering, Nanofibers, Biochemistry, Article, Biomaterials, Rats, Sprague-Dawley, Tissue engineering, In vivo, medicine, Animals, Scattering, Radiation, Molecular Biology, Tissue Engineering, Tissue Scaffolds, Guided Tissue Regeneration, X-Rays, Intervertebral disc, General Medicine, Equipment Design, Electroplating, Tendon, Equipment Failure Analysis, medicine.anatomical_structure, Ligament, Cattle, Tomography, X-Ray Computed, Ex vivo, Biotechnology, Biomedical engineering

Abstract

Tissue engineering strategies have emerged in response to the growing prevalence of chronic musculoskeletal conditions, with many of these regenerative methods currently being evaluated in translational animal models. Engineered replacements for fibrous tissues such as the meniscus, annulus fibrosus, tendons, and ligaments are subjected to challenging physiologic loads, and are difficult to track in vivo using standard techniques. The diagnosis and treatment of musculoskeletal conditions depends heavily on radiographic assessment, and a number of currently available implants utilize radiopaque markers to facilitate in vivo imaging. In this study, we developed a nanofibrous scaffold in which individual fibers included radiopaque nanoparticles. Inclusion of radiopaque particles increased the tensile modulus of the scaffold and imparted radiation attenuation within the range of cortical bone. When scaffolds were seeded with bovine mesenchymal stem cells in vitro, there was no change in cell proliferation and no evidence of promiscuous conversion to an osteogenic phenotype. Scaffolds were implanted ex vivo in a model of a meniscal tear in a bovine joint and in vivo in a model of total disc replacement in the rat coccygeal spine (tail), and were visualized via fluoroscopy and microcomputed tomography. In the disc replacement model, histological analysis at 4 weeks showed that the scaffold was biocompatible and supported the deposition of fibrous tissue in vivo. Nanofibrous scaffolds that include radiopaque nanoparticles provide a biocompatible template with sufficient radiopacity for in vivo visualization in both small and large animal models. This radiopacity may facilitate image-guided implantation and non-invasive long-term evaluation of scaffold location and performance. Statement of Significance The healing capacity of fibrous musculoskeletal tissues is limited, and injury or degeneration of these tissues compromises the standard of living of millions in the US. Tissue engineering repair strategies for the intervertebral disc, meniscus, tendon and ligament have progressed from in vitro to in vivo evaluation using a variety of animal models, and the clinical application of these technologies is imminent. The composition of most scaffold materials however does not allow for visualization by methods available to clinicians (e.g., radiography), and thus it is not possible to assess their performance in situ. In this work, we describe a radiopaque nanofibrous scaffold that can be visualized radiographically in both small and large animal models and serve as a framework for the development of an engineered fibrous tissue.

Published

2015