Localization of vascular endothelial growth factor during the early stages of osteochondral regeneration using a bioabsorbable synthetic polymer scaffold

Sakata, Ryosuke; Kokubu, Tatsuo; Nagura, Issei; Toyokawa, Narikazu; Inui, Atsuyuki; Fujioka, Hiroyuki; Kurosaka, Masahiro

doi:10.1002/jor.21502

Cited by 15 publications

(13 citation statements)

References 31 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Previous chitosan-induced cartilage repair studies in rabbits have documented neutrophil chemotaxis at 21 days that is associated with a delay in matrix deposition, as observed in the current study [9,26]. The benefits of delayed matrix deposition after three weeks was also demonstrated in defects treated with PLG subchondral implants in rabbits, although implant clearance was not specifically reported and evidence of neutrophil or osteoclast attraction was not shown [3,27]. Most importantly, in a separate study, 10K pre-solidified chitosan-NaCl/blood implants elicited hyaline-like cartilage repair tissue and delayed callus formation compared to drill-only defects after 2.5 months in skeletally aged rabbits [28].…”

Section: Discussionsupporting

confidence: 71%

Subchondral pre-solidified chitosan/blood implants elicit reproducible early osteochondral wound-repair responses including neutrophil and stromal cell chemotaxis, bone resorption and repair, enhanced repair tissue integration and delayed matrix deposition

Lafantaisie-Favreau

Guzmán-Morales

Sun

et al. 2013

BMC Musculoskelet Disord

View full text Add to dashboard Cite

BackgroundIn this study we evaluated a novel approach to guide the bone marrow-driven articular cartilage repair response in skeletally aged rabbits. We hypothesized that dispersed chitosan particles implanted close to the bone marrow degrade in situ in a molecular mass-dependent manner, and attract more stromal cells to the site in aged rabbits compared to the blood clot in untreated controls.MethodsThree microdrill hole defects, 1.4 mm diameter and 2 mm deep, were created in both knee trochlea of 30 month-old New Zealand White rabbits. Each of 3 isotonic chitosan solutions (150, 40, 10 kDa, 80% degree of deaceylation, with fluorescent chitosan tracer) was mixed with autologous rabbit whole blood, clotted with Tissue Factor to form cylindrical implants, and press-fit in drill holes in the left knee while contralateral holes received Tissue Factor or no treatment. At day 1 or day 21 post-operative, defects were analyzed by micro-computed tomography, histomorphometry and stereology for bone and soft tissue repair.ResultsAll 3 implants filled the top of defects at day 1 and were partly degraded in situ at 21 days post-operative. All implants attracted neutrophils, osteoclasts and abundant bone marrow-derived stromal cells, stimulated bone resorption followed by new woven bone repair (bone remodeling) and promoted repair tissue-bone integration. 150 kDa chitosan implant was less degraded, and elicited more apoptotic neutrophils and bone resorption than 10 kDa chitosan implant. Drilled controls elicited a poorly integrated fibrous or fibrocartilaginous tissue.ConclusionsPre-solidified implants elicit stromal cells and vigorous bone plate remodeling through a phase involving neutrophil chemotaxis. Pre-solidified chitosan implants are tunable by molecular mass, and could be beneficial for augmented marrow stimulation therapy if the recruited stromal cells can progress to bone and cartilage repair.

show abstract

Section: Discussionsupporting

confidence: 71%

Subchondral pre-solidified chitosan/blood implants elicit reproducible early osteochondral wound-repair responses including neutrophil and stromal cell chemotaxis, bone resorption and repair, enhanced repair tissue integration and delayed matrix deposition

Lafantaisie-Favreau

Guzmán-Morales

Sun

et al. 2013

BMC Musculoskelet Disord

View full text Add to dashboard Cite

show abstract

“…These results suggest that during osteochondral defect repair, robust tissue formation can be induced by promoting and inhibiting angiogenesis within the subchondral and chondral regions respectively. It is interesting to note that within a rabbit model, in osteochondral defects treated with a bioabsorbable scaffold which induced regeneration of the cartilage tissue in the superficial layer, the pro‐angiogenic factor VEGF was localized in the subchondral region of the defect . In the same study, in untreated defects VEGF was localized throughout the entire defect and no cartilage regeneration was observed …”

Section: Discussionmentioning

confidence: 84%

Role of oxygen as a regulator of stem cell fate during the spontaneous repair of osteochondral defects

O'Reilly

Kelly

2015

Journal Orthopaedic Research

View full text Add to dashboard Cite

The complexity of the in vivo environment makes it is difficult to isolate the effects of specific cues on regulating cell fate during regenerative events such as osteochondral defect repair. The objective of this study was to develop a computational model to explore how joint specific environmental factors regulate mesenchymal stem cell (MSC) fate during osteochondral defect repair. To this end, the spontaneous repair process within an osteochondral defect was simulated using a tissue differentiation algorithm which assumed that MSC fate was regulated by local oxygen levels and substrate stiffness. The developed model was able to predict the main stages of tissue formation observed by a number of in vivo studies. Following this, a parametric study was conducted to better understand why interventions that modulate angiogenesis dramatically impact the outcome of osteochondral defect healing. In the simulations where angiogenesis was reduced, by week 12, the subchondral plate was predicted to remain below the native tidemark, although the chondral region was composed entirely of cartilage and fibrous tissue. In the simulations where angiogenesis was increased, more robust cell proliferation and cartilage formation were observed during the first 4 weeks, however, by week 12 the subchondral plate had advanced above the native tidemark although any remaining tissue was either hypertrophic cartilage or fibrous tissue. These results suggest that osteochondral defect repair could be enhanced by interventions where angiogenesis is promoted but confined to within the subchondral region of the defect. The environmental factors regulating this spontaneous repair process however remain poorly understood, with previous computational models suggesting that biomechanical signals may play a key role in directing stem cell fate during osteochondral defect repair. 4 Recently, excessive bone formation during joint regeneration has been linked with vascular invasion of the defect site. Klinger et al.5 examined the effect of inhibiting angiogenesis within a porcine model of cartilage repair by microfracture. In this study, angiogenesis was inhibited by over expressing the antiangiogenic factor chondromodulin 1. This resulted in less vascular invasion, an inhibition of chondrocyte hypertrophy and endochondral ossification, as well as more robust hyaline cartilage formation at later time points. Similar results were observed by Nagai et al. 6 within a rabbit model of spontaneous osteochondral defect repair, where administration of an anti-vascular endothelial growth factor was used to inhibit angiogenesis. Both of these studies point to the importance of angiogenesis and associated local oxygen levels in regulating chondrogenesis and endochondral ossification during osteochondral defect repair.Based on these findings and recent studies which have shown that hypertrophy of chondrocytes is supressed in hypoxic or low oxygen conditions, 7-11 we hypothesized that local oxygen levels are a critical determinant of the success of os...

show abstract

“…Bone overgrowth within osteochondral defects was shown to be promoted by growth factors such as transforming growth factor beta1 37 , or bone morphogenetic proteins 38 . In addition, angiogenesis promoted subchondral bone plate migration: Sakata et al 39 suggested that vascular endothelial growth factor might favour subchondral bone overgrowth in rabbits. Vice versa, the anti-angiogenic factors chondromodulin-I 40 and thrombospondin-1 38 , as expressed e.g., by implanted articular chondrocytes 41 , or other compounds 42 may prevent this inadvertent stimulation of osseous overgrowth.…”

Section: Discussionmentioning

confidence: 98%

Temporal and spatial migration pattern of the subchondral bone plate in a rabbit osteochondral defect model

Orth

Cucchiarini

Kaul

et al. 2012

Osteoarthritis and Cartilage

View full text Add to dashboard Cite

show abstract

Localization of vascular endothelial growth factor during the early stages of osteochondral regeneration using a bioabsorbable synthetic polymer scaffold

Cited by 15 publications

References 31 publications

Subchondral pre-solidified chitosan/blood implants elicit reproducible early osteochondral wound-repair responses including neutrophil and stromal cell chemotaxis, bone resorption and repair, enhanced repair tissue integration and delayed matrix deposition

Subchondral pre-solidified chitosan/blood implants elicit reproducible early osteochondral wound-repair responses including neutrophil and stromal cell chemotaxis, bone resorption and repair, enhanced repair tissue integration and delayed matrix deposition

Role of oxygen as a regulator of stem cell fate during the spontaneous repair of osteochondral defects

Temporal and spatial migration pattern of the subchondral bone plate in a rabbit osteochondral defect model

Contact Info

Product

Resources

About