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Redlich, A.; Perka, Carsten; Schultz, Olaf; Spitzer, Ron-Sascha; ̈upl, T. Ha; Burmester, Gerd R.; Sittinger, Michael

doi:10.1023/a:1008994715605

Cited by 43 publications

(3 citation statements)

References 17 publications

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“…However, harvesting PDPCs, laboratory expenses, and the necessary time for construct preparation, should be planned early enough before the surgical resection to avoid possible morbidity. When PDPCs were seeded into polyglycolide-co-polylactide scaffold to repair critical size bone defects in a rabbit model, they showed satisfactory outcomes [ Redlich et al,1999 ]. The success of surgical reconstruction relies on the potential of healthy patient’s cells that surround the defect site, to infiltrate and vascularize the tissue engineered construct.…”

Section: Oral and Maxillofacial Engineered Tissuesmentioning

confidence: 99%

Bioengineering from the laboratory to clinical translation in oral and maxillofacial reconstruction

Maria,

Heram,

Tran

2024

The Saudi Dental Journal

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Section: Oral and Maxillofacial Engineered Tissuesmentioning

confidence: 99%

Bioengineering from the laboratory to clinical translation in oral and maxillofacial reconstruction

Maria,

Heram,

Tran

2024

The Saudi Dental Journal

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“…In contrast to bMSCs, which are restricted to the bone marrow compartment during bone repair and indirectly stimulate healing via the secretion of growth factors [ 74 ], PDCs are directly involved in bone repair [ 18 ]. Thus, PDCs have been used to generate in situ bone tissue for fracture healing or bridging of critical-sized defects in combination with various scaffolds [ 81 , 82 ]…”

Section: The Periosteummentioning

confidence: 99%

The periosteum: a simple tissue with many faces, with special reference to the antler-lineage periostea

Fennessy²

2021

Biol Direct

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Periosteum is a thin membrane covering bone surfaces and consists of two layers: outer fibrous layer and inner cambium layer. Simple appearance of periosteum has belied its own complexity as a composite structure for physical bone protection, mechano-sensor for sensing mechanical loading, reservoir of biochemical molecules for initiating cascade signaling, niche of osteogenic cells for bone formation and repair, and “umbilical cord” for nourishing bone tissue. Periosteum-derived cells (PDCs) have stem cell attributes: self-renewal (no signs of senescence until 80 population doublings) and multipotency (differentiate into fibroblasts, osteoblasts, chondrocytes, adipocytes and skeletal myocytes). In this review, we summarized the currently available knowledge about periosteum and with special references to antler-lineage periostea, and demonstrated that although periosteum is a type of simple tissue in appearance, with multiple faces in functions; antler-lineage periostea add another dimension to the properties of somatic periostea: capable of initiation of ectopic organ formation upon transplantation and full mammalian organ regeneration when interacted with the covering skin. Very recently, we have translated this finding into other mammals, i.e. successfully induced partial regeneration of the amputated rat legs. We believe further refinement along this line would greatly benefit human health.

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“…28–32 Indeed, PDCs have been combined with biomaterials in lieu of the bone marrow-derived MSCs for various bone tissue engineering applications. 33 Like bone marrow-derived MSCs, the differentiation of PDCs can also be profoundly impacted by the scaffold environment that they adhere to, underscoring the importance of choosing a suitable biomaterial scaffold for the delivery of exogenous PDCs to promote bone healing. 34 In this study, we demonstrate the advantages of rat PDCs over bone marrow-derived MSCs in terms of their in vitro proliferation and osteogenic differentiation potential.…”

Section: Introductionmentioning

confidence: 99%

A Sulfated Nanofibrous Mesh Supporting the Osteogenic Differentiation of Periosteum-Derived Cells

Filion

Song

2013

j biomat tissue engng

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The periosteum is a thin fibrous membrane covering the surface of long bone and is known to play a critical role in bone development and adult bone fracture healing. Loss or damage of the periosteum tissue during traumatic long bone injuries can lead to retarded healing of bone graft-mediated repair. The regenerative potential of periosteum-derived progenitor cells (PDCs) has inspired their use as an alternative to bone marrow-derived mesenchymal stromal cells (MSCs) to augment scaffold-assisted bone repair. In this study, we first demonstrated that PDCs isolated from adult rat long bone exhibited innate advantages over bone marrow-derived MSCs in terms of faster proliferation and more potent osteogenic differentiation upon induction in plastic-adherent culture. Further, we examined the potential of two electrospun nanofibrous meshes, an uncharged regenerated cellulose mesh and a sulfated mesh, to support the attachment and osteogenic differentiation of PDCs. We showed that both nanofibrous meshes were able to support the attachment and proliferation of PDCs and MSCs alike, with the sulfated mesh enabling significantly higher seeding efficiency than the cellulose mesh. Both meshes were also able to support the osteogenic differentiation of adherent PDCs upon induction by osteogenic media, with the sulfated mesh facilitating more potent mineral deposition by adherent PDCs. Our study supports the sulfated nanofibrous mesh as a promising synthetic periosteal membrane for the delivery of exogenous PDCs to augment bone healing.

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Cited by 43 publications

References 17 publications

Bioengineering from the laboratory to clinical translation in oral and maxillofacial reconstruction

Bioengineering from the laboratory to clinical translation in oral and maxillofacial reconstruction

The periosteum: a simple tissue with many faces, with special reference to the antler-lineage periostea

A Sulfated Nanofibrous Mesh Supporting the Osteogenic Differentiation of Periosteum-Derived Cells

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