Nicholas W. Clavin scite author profile

Soft-tissue fibrosis is associated with impairment in lymphatic regeneration and lymphatic function. These defects occur as a consequence of impaired lymphatic endothelial cell proliferation, abnormal lymphatic microarchitecture, and lymphatic fibrosis. Inhibition of fibrosis using a simple topical dressing can markedly accelerate lymphatic repair and promote regeneration of normal capillary lymphatics.

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Synthesis of a Tissue-Engineered Periosteum with Acellular Dermal Matrix and Cultured Mesenchymal Stem Cells

Schönmeyr

Clavin

Avraham

et al. 2009

Tissue Engineering Part A

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Periosteal grafts can aid in bone repair by providing bone progenitor cells and acting as a barrier to scar tissue. Unfortunately, these grafts have many of the same disadvantages as bone grafts (donor site morbidity and limited donor sites). In this article, we describe a method of synthesizing a periosteum-like material using acellular human dermis and osteoblasts or mesenchymal stem cells (MSC). We show that osteoblasts readily attach to and proliferate on the acellular human dermis in vitro. In addition, osteoblasts retained the potential for differentiation in response to bone morphogenetic protein stimulation. Cells grown on the acellular human dermis were efficiently transfected with adenoviruses with no evidence of cellular toxicity. To assess for in vivo cell delivery and bone-forming potential, the acellular human dermis was seeded with green fluorescent protein (GFP)-positive MSCs, transfected with bone morphogenetic protein 2, wrapped around the adductor muscle in syngeneic mice, and used to treat critical-sized mandibular defects in nude rats. After 3 weeks, GFP-positive cells were still present, and bone had replaced the interface between the muscle and the constructs. After 6 weeks, critical-sized bone defects had been successfully healed. In conclusion, we show that an acellular human dermis can be used to synthesize a tissue-engineered periosteum capable of delivering cells and osteoinductive proteins.

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Ionizing Radiation of Mesenchymal Stem Cells Results in Diminution of the Precursor Pool and Limits Potential for Multilineage Differentiation

Schönmeyr¹,

Wong²,

Soares³

et al. 2008

Plastic and Reconstructive Surgery

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Although the majority of mesenchymal stem cells survive injury from ionizing radiation, this injury results in a significant decrease in cellular proliferation. Furthermore, the differentiation potential of irradiated mesenchymal stem cells in response to environmental stimuli is markedly diminished. Thus, the negative effects of ionizing radiation may result from a decreased pool of progenitor cells with limited differentiation potential. Proposed radioprotection strategies aiming to reduce tissue injury should therefore evaluate not only cellular survival but also cellular function.

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