2010
DOI: 10.1073/pnas.0907774107
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Autologous engineering of cartilage

Abstract: Treatment of full-thickness damage to hyaline cartilage is hampered by the limited availability of autologous healthy cartilage and the lengthy, cost-prohibitive cell isolation and expansion steps associated with autologous cartilage implantation (ACI). Here we report a strategy for de novo engineering of ectopic autologous cartilage (EAC) within the subperiosteal space (in vivo bioreactor), through the mere introduction of a biocompatible gel that might promote hypoxia-mediated chondrogenesis, thereby effecti… Show more

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Cited by 72 publications
(69 citation statements)
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“…[5] However, formulating these materials with specific mechanical properties for 3D printing requires both optimization of the formulation and the 3D printing parameters. Agarose, a polysaccharide that undergoes thermally reversible gelation and is stable under physiological conditions, has been explored in cartilage repair, [19] as an injectable tissue filler, [20] and synthetic 3D cell matrix. [21] More recently, agarose has been explored as a bioink for the 3D printing of umbilical artery endothelial cells; [22] however, tailoring mechanical properties of agarose gels requires changing the concentration of agarose and this profoundly impacts its rheological behavior, thus limiting its utilization as a mechanically tunable bioink.…”
mentioning
confidence: 99%
“…[5] However, formulating these materials with specific mechanical properties for 3D printing requires both optimization of the formulation and the 3D printing parameters. Agarose, a polysaccharide that undergoes thermally reversible gelation and is stable under physiological conditions, has been explored in cartilage repair, [19] as an injectable tissue filler, [20] and synthetic 3D cell matrix. [21] More recently, agarose has been explored as a bioink for the 3D printing of umbilical artery endothelial cells; [22] however, tailoring mechanical properties of agarose gels requires changing the concentration of agarose and this profoundly impacts its rheological behavior, thus limiting its utilization as a mechanically tunable bioink.…”
mentioning
confidence: 99%
“…The hypercellular cartilage induced within the IVB, was harvested during its early chondrogenic phase and successfully implanted into an osteochondral defect where excellent lateral integration into the subchondral bone as well as in the articular cartilage was observed. Importantly, absence of ossification of the transplanted ectopically produced cartilage was observed in a long term followup study [48].…”
Section: In Vivo Differentiation Of Periosteum To Generate Cartilagementioning
confidence: 91%
“…They also went on to demonstrate chondrogenesis within the IVB by the injection of a hyaluronic acid-based gel containing the anti-angiogenic factor Suramin. In this system the inhibition of angiogenesis provided the hypoxic character to the biogel-environment which was likely to favour the formation of cartilage that resembles early fracture callus [48,49]. Following the initial report, which focused on bone, we aimed to achieve controlled chondrogenesis within the IVB and control the local subperiosteal environment by simply injecting a gel to initiate the endochondral process.…”
Section: In Vivo Differentiation Of Periosteum To Generate Cartilagementioning
confidence: 99%
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“…The translation from "bench to bedside" requires significant input from the clinicians with respect to adaptation of prevailing standards in surgical intervention to the development of new biomaterials. A good example of such a collaborative approach is the in vivo bioreactor paradigm [13,14]. In the in vivo bioreactor paradigm, the de novo formation of a fully functional bone or cartilage is invoked and controlled purely through the minimally invasive placement of a biomaterial with precise physicochemical characteristics.…”
mentioning
confidence: 99%