Student research award in the doctoral degree candidate category, Society for Biomaterials 23rd Annual Meeting, New Orleans, LA, April 30-May 4, 1997: Ectopic bone formation by marrow stromal osteoblast transplantation using poly(DL-lactic-co-glycolic acid) foams implanted into the rat mesentery

Ishaug-Riley, Susan L.; Crane, Genevieve M.; Gürlek, Ali; Miller, Michael J.; Yasko, Alan W.; Yaszemski, Michael J.; Mikos, Antonios G.

doi:10.1002/(sici)1097-4636(199707)36:1<1::aid-jbm1>3.0.co;2-p

Cited by 242 publications

(28 citation statements)

References 18 publications

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“…Many scaffold fabrication techniques previously reported have resulted in an uneven distribution of cells within the construct [13,14,15]. In the case of most in vivo tissue , a network of vascularization offers a maximum nutrient diffusion distance of about 200 μm, which is most likely the reason why most successful tissue engineered applications have resulted in the growth of tissues with cross sections less than 500 μm from the external surface of the scaffold [17,26].…”

Section: Resultsmentioning

confidence: 99%

“…Many scaffold processing and fabrication techniques such as fiber meshes [5], phase separation [6], solvent casting and particulate leaching [7], membrane lamination [8], and melt molding [9] have been utilized in a wide variety of applications including bone [10], cartilage [11], blood vessels [12], and heart valves [13]. Although these scaffolds have demonstrated promise, uneven cell distribution and nutrient delivery in the deep portion of the synthetic scaffolds (> 200 μm) due to the random mobility of cell suspension often compromise their successful uses in tissue engineering [14,15]. The seeded cells and matrix produced by cells at the scaffold periphery also act as a barrier to the diffusion of oxygen and nutrients into the interior of the scaffold.…”

Section: Introductionmentioning

confidence: 99%

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Scaffold Sheet Design Strategy for Soft Tissue Engineering

et al. 2010

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Creating heterogeneous tissue constructs with an even cell distribution and robust mechanical strength remain important challenges to the success of in vivo tissue engineering. To address these issues, we are developing a scaffold sheet tissue engineering strategy consisting of thin (~200 μm), strong, elastic, and porous crosslinked urethane-doped polyester (CUPE) scaffold sheets that are bonded together chemically or through cell culture. Suture retention of the tissue constructs (four sheets) fabricated by the scaffold sheet tissue engineering strategy is close to the surgical requirement (1.8 N) rendering their potential for immediate implantation without a need for long cell culture times. Cell culture results using 3T3 fibroblasts show that the scaffold sheets are bonded into a tissue construct via the extracellular matrix produced by the cells after 2 weeks of in vitro cell culture.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Scaffold Sheet Design Strategy for Soft Tissue Engineering

et al. 2010

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“…Their chemical versatility and processability varies according to their structure and nature, and hence a direct comparison with the natural polymers can not be established. The most widely used are poly( α ‐hydroxy acids),106–129 poly( ε ‐caprolactone),130–135 poly(propylene fumarates),127,136–144 poly(carbonates),145–149 poly(phosphazenes),127,150–152 and poly(anhydrides) 127,153,154. Further details on the origin and characteristics of these materials can be found in Table 3.…”

Section: Tissue Engineeringmentioning

confidence: 99%

“…Current state of the art within the bone TE field consists of the use of MSCs isolated from the bone marrow combined with 3D biodegradable porous scaffolds 34,55,57,60–63,108,120,279–282. It is known that when exposed to dexamethasone they differentiate towards the osteogenic lineage 210.…”

Section: Tissue Engineering Strategiesmentioning

confidence: 99%

Bone Tissue Engineering: State of the Art and Future Trends

Salgado

Coutinho

Reis

2004

Macromolecular Bioscience

1,506

1,179

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Although several major progresses have been introduced in the field of bone regenerative medicine during the years, current therapies, such as bone grafts, still have many limitations. Moreover, and in spite of the fact that material science technology has resulted in clear improvements in the field of bone substitution medicine, no adequate bone substitute has been developed and hence large bone defects/injuries still represent a major challenge for orthopaedic and reconstructive surgeons. It is in this context that TE has been emerging as a valid approach to the current therapies for bone regeneration/substitution. In contrast to classic biomaterial approach, TE is based on the understanding of tissue formation and regeneration, and aims to induce new functional tissues, rather than just to implant new spare parts. The present review pretends to give an exhaustive overview on all components needed for making bone tissue engineering a successful therapy. It begins by giving the reader a brief background on bone biology, followed by an exhaustive description of all the relevant components on bone TE, going from materials to scaffolds and from cells to tissue engineering strategies, that will lead to "engineered" bone. Scaffolds processed by using a methodology based on extrusion with blowing agents.

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“…In order to fulfill both the mechanical strength and provide environment conducive for vascularization, PLGA scaffolds have especially been deemed viable candidates for bone tissue engineering, particularly when blended with other bioactive materials for greater cell attachment [64,182]. Sheik et al recently presented a novel PLGA/silk hybrid scaffold for bone tissue engineering applications in which the degradation rate of PLGA was combined with the hydrophilic silk polymer, as well as hydroxyapatite nanoparticles to further improve biocompatibility, and effectiveness was evaluated both in vitro and in vivo [183].…”

Section: Applicationsmentioning

confidence: 99%

Bioactive polymeric scaffolds for tissue engineering

Stratton

Shelke

Hoshino

et al. 2016

Bioactive Materials

383

225

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A variety of engineered scaffolds have been created for tissue engineering using polymers, ceramics and their composites. Biomimicry has been adopted for majority of the three-dimensional (3D) scaffold design both in terms of physicochemical properties, as well as bioactivity for superior tissue regeneration. Scaffolds fabricated via salt leaching, particle sintering, hydrogels and lithography have been successful in promoting cell growth in vitro and tissue regeneration in vivo. Scaffold systems derived from decellularization of whole organs or tissues has been popular due to their assured biocompatibility and bioactivity. Traditional scaffold fabrication techniques often failed to create intricate structures with greater resolution, not reproducible and involved multiple steps. The 3D printing technology overcome several limitations of the traditional techniques and made it easier to adopt several thermoplastics and hydrogels to create micro-nanostructured scaffolds and devices for tissue engineering and drug delivery. This review highlights scaffold fabrication methodologies with a focus on optimizing scaffold performance through the matrix pores, bioactivity and degradation rate to enable tissue regeneration. Review highlights few examples of bioactive scaffold mediated nerve, muscle, tendon/ligament and bone regeneration. Regardless of the efforts required for optimization, a shift in 3D scaffold uses from the laboratory into everyday life is expected in the near future as some of the methods discussed in this review become more streamlined.

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Student research award in the doctoral degree candidate category, Society for Biomaterials 23rd Annual Meeting, New Orleans, LA, April 30-May 4, 1997: Ectopic bone formation by marrow stromal osteoblast transplantation using poly(DL-lactic-co-glycolic acid) foams implanted into the rat mesentery

Cited by 242 publications

References 18 publications

Scaffold Sheet Design Strategy for Soft Tissue Engineering

Scaffold Sheet Design Strategy for Soft Tissue Engineering

Bone Tissue Engineering: State of the Art and Future Trends

Bioactive polymeric scaffolds for tissue engineering

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