Vasculature is essential to the functional integration of a tissue-engineered bone graft to enable sufficient nutrient delivery and viability after implantation. Native bone and vasculature develop through intimately coupled, tightly regulated spatiotemporal cell–cell signaling. The complexity of these developmental processes has been a challenge for tissue engineers to recapitulate, resulting in poor codevelopment of both bone and vasculature within a unified graft. To address this, we cultured adipose-derived stromal/stem cells (ASCs), a clinically relevant, single cell source that has been previously investigated for its ability to give rise to vascularized bone grafts, and studied the effects of initial spatial organization of cells, the temporal addition of growth factors, and the presence of exogenous platelet-derived growth factor-BB (PDGF-BB) on the codevelopment of bone and vascular tissue structures. Human ASCs were aggregated into multicellular spheroids via the hanging drop method before encapsulation and subsequent outgrowth in fibrin gels. Cellular aggregation substantially increased vascular network density, interconnectivity, and pericyte coverage compared to monodispersed cultures. To form robust vessel networks, it was essential to culture ASCs in a purely vasculogenic medium for at least 8 days before the addition of osteogenic cues. Physiologically relevant concentrations of exogenous PDGF-BB (20 ng/mL) substantially enhanced both vascular network stability and osteogenic differentiation. Comparisons with the bone morphogenetic protein-2, another pro-osteogenic and proangiogenic growth factor, indicated that this potential to couple the formation of both lineages might be unique to PDGF-BB. Furthermore, the resulting tissue structure demonstrated the close association of mineral deposits with pre-existing vascular structures that have been described for developing tissues. This combination of a single cell source with a potent induction factor used at physiological concentrations can provide a clinically relevant approach to engineering highly vascularized bone grafts.
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References
1.
QuartoN., LongakerM.T.FGF-2 inhibits osteogenesis in mouse adipose tissue-derived stromal cells and sustains their proliferative and osteogenic potential state. Tissue Eng, 12:1405. 2006.
2.
MeuryT., VerrierS., AliniM.Human endothelial cells inhibit BMSC differentiation into mature osteoblasts in vitro by interfering with osterix expression. J Cell Biochem, 98:992. 2006.
3.
HoriY., HuD.E., YasuiK., SmitherR.L., GreshamG.A., FanT.P.Differential effects of angiostatic steroids and dexamethasone on angiogenesis and cytokine levels in rat sponge implants. Br J Pharmacol, 118:1584. 1996.
4.
CorreiaC., GraysonW., EtonR., GimbleJ.M., SousaR.A., ReisR.L.et al.Human adipose-derived cells can serve as a single-cell source for the in vitro cultivation of vascularized bone grafts. J Tissue Eng Regen Med, 2012[Epub ahead of print]10.1002/term.1564.
5.
CorreiaC., GraysonW.L., ParkM., HuttonD., ZhouB., GuoX.E.et al.In vitro model of vascularized bone: synergizing vascular development and osteogenesis. PLoS One, 6:e28352. 2011.
6.
TsigkouO., PomerantsevaI., SpencerJ.A., RedondoP.A., HartA.R., O'DohertyE.et al.Engineered vascularized bone grafts. Proc Natl Acad Sci U S A, 107:3311. 2010.
7.
RouwkemaJ., de BoerJ., Van BlitterswijkC.A.Endothelial cells assemble into a 3-dimensional prevascular network in a bone tissue engineering construct. Tissue Eng, 12:2685. 2006.
8.
LiuY., TeohS.H., ChongM.S., LeeE.S., MattarC.N., RandhawaN.K.et al.Vasculogenic and osteogenesis-enhancing potential of human umbilical cord blood endothelial colony-forming cells. Stem Cells, 30:1911. 2012.
9.
UsamiK., MizunoH., OkadaK., NaritaY., AokiM., KondoT.et al.Composite implantation of mesenchymal stem cells with endothelial progenitor cells enhances tissue-engineered bone formation. J Biomed Mater Res A, 90:730. 2009.
10.
KoobS., Torio-PadronN., StarkG.B., HannigC., StankovicZ., FinkenzellerG.Bone formation and neovascularization mediated by mesenchymal stem cells and endothelial cells in critical-sized calvarial defects. Tissue Eng Part A, 17:311. 2011.
11.
NishiM., MatsumotoR., DongJ., UemuraT.Engineered bone tissue associated with vascularization utilizing a rotating wall vessel bioreactor. J Biomed Mater Res A, 101:421. 2013.
HuttonD.L., LogsdonE.A., MooreE.M., Mac GabhannF., GimbleJ.M., GraysonW.L.Vascular morphogenesis of adipose-derived stem cells is mediated by heterotypic cell-cell interactions. Tissue Eng Part A, 18:1729. 2012.
17.
MiranvilleA., HeeschenC., SengenesC., CuratC.A., BusseR., BouloumieA.Improvement of postnatal neovascularization by human adipose tissue-derived stem cells. Circulation, 110:349. 2004.
18.
Planat-BenardV., SilvestreJ.S., CousinB., AndreM., NibbelinkM., TamaratR.et al.Plasticity of human adipose lineage cells toward endothelial cells: physiological and therapeutic perspectives. Circulation, 109:656. 2004.
19.
BoquestA.C., NoerA., SorensenA.L., VekterudK., CollasP.CpG methylation profiles of endothelial cell-specific gene promoter regions in adipose tissue stem cells suggest limited differentiation potential toward the endothelial cell lineage. Stem Cells, 25:852. 2007.
20.
KohY.J., KohB.I., KimH., JooH.J., JinH.K., JeonJ.et al.Stromal vascular fraction from adipose tissue forms profound vascular network through the dynamic reassembly of blood endothelial cells. Arterioscler Thromb Vasc Biol, 31:1141. 2011.
21.
GardinC., BressanE., FerroniL., NalessoE., VindigniV., StelliniE.et al.In vitro concurrent endothelial and osteogenic commitment of adipose-derived stem cells and their genomical analyses through comparative genomic hybridization array: novel strategies to increase the successful engraftment of tissue-engineered bone grafts. Stem Cells Dev, 21:767. 2012.
22.
GuvenS., MehrkensA., SaxerF., SchaeferD.J., MartinettiR., MartinI.et al.Engineering of large osteogenic grafts with rapid engraftment capacity using mesenchymal and endothelial progenitors from human adipose tissue. Biomaterials, 32:5801. 2011.
23.
MullerA.M., MehrkensA., SchaferD.J., JaquieryC., GuvenS., LehmickeM.et al.Towards an intraoperative engineering of osteogenic and vasculogenic grafts from the stromal vascular fraction of human adipose tissue. Eur Cell Mater, 19:127. 2010.
24.
LiuY., ChanJ.K., TeohS.H.Review of vascularised bone tissue-engineering strategies with a focus on co-culture systems. J Tissue Eng Regen Med, 2012[Epub ahead of print]10.1002/term.1617.
BergersG., SongS.The role of pericytes in blood-vessel formation and maintenance. Neuro Oncol, 7:452. 2005.
27.
CaplanA.I., CorreaD.PDGF in bone formation and regeneration: new insights into a novel mechanism involving MSCs. J Orthop Res, 29:1795. 2011.
28.
SolheimE.Growth factors in bone. Int Orthop, 22:410. 1998.
29.
AndrewJ.G., HoylandJ.A., FreemontA.J., MarshD.R.Platelet-derived growth factor expression in normally healing human fractures. Bone, 16:455. 1995.
30.
GrahamS., LeonidouA., LesterM., HeliotisM., MantalarisA., TsiridisE.Investigating the role of PDGF as a potential drug therapy in bone formation and fracture healing. Expert Opin Investig Drugs, 18:1633. 2009.
31.
ParkY.J., LeeY.M., ParkS.N., SheenS.Y., ChungC.P., LeeS.J.Platelet derived growth factor releasing chitosan sponge for periodontal bone regeneration. Biomaterials, 21:153. 2000.
32.
NashT.J., HowlettC.R., MartinC., SteeleJ., JohnsonK.A., HicklinD.J.Effect of platelet-derived growth factor on tibial osteotomies in rabbits. Bone, 15:203. 1994.
33.
ChaudharyL.R., HofmeisterA.M., HruskaK.A.Differential growth factor control of bone formation through osteoprogenitor differentiation. Bone, 34:402. 2004.
34.
KumarA., SalimathB.P., StarkG.B., FinkenzellerG.Platelet-derived growth factor receptor signaling is not involved in osteogenic differentiation of human mesenchymal stem cells. Tissue Eng Part A, 16:983. 2010.
35.
TanakaH., LiangC.T.Effect of platelet-derived growth factor on DNA synthesis and gene expression in bone marrow stromal cells derived from adult and old rats. J Cell Physiol, 164:367. 1995.
36.
GruberR., KarrethF., KandlerB., FuerstG., RotA., FischerM.B.et al.Platelet-released supernatants increase migration and proliferation, and decrease osteogenic differentiation of bone marrow-derived mesenchymal progenitor cells under in vitro conditions. Platelets, 15:29. 2004.
37.
TokunagaA., OyaT., IshiiY., MotomuraH., NakamuraC., IshizawaS.et al.PDGF receptor beta is a potent regulator of mesenchymal stromal cell function. J Bone Miner Res, 23:1519. 2008.
38.
LeeJ., GuptaD., PanettaN.J., LeviB., JamesA.W., WanD.et al.Elucidating mechanisms of osteogenesis in human adipose-derived stromal cells via microarray analysis. J Craniofac Surg, 21:1136. 2010.
39.
DuboisS.G., FloydE.Z., ZvonicS., KilroyG., WuX., CarlingS.et al.Isolation of human adipose-derived stem cells from biopsies and liposuction specimens. Methods Mol Biol, 449:69. 2008.
40.
GohB.C., ThirumalaS., KilroyG., DevireddyR.V., GimbleJ.M.Cryopreservation characteristics of adipose-derived stem cells: maintenance of differentiation potential and viability. J Tissue Eng Regen Med, 1:322. 2007.
41.
NiemistoA., DunmireV., Yli-HarjaO., ZhangW., ShmulevichI.Robust quantification of in vitro angiogenesis through image analysis. IEEE Trans Med Imaging, 24:549. 2005.
42.
ChenX., AlediaA.S., GhajarC.M., GriffithC.K., PutnamA.J., HughesC.C.et al.Prevascularization of a fibrin-based tissue construct accelerates the formation of functional anastomosis with host vasculature. Tissue Eng Part A, 15:1363. 2009.
UngerR.E., GhanaatiS., OrthC., SartorisA., BarbeckM., HalstenbergS.et al.The rapid anastomosis between prevascularized networks on silk fibroin scaffolds generated in vitro with cocultures of human microvascular endothelial and osteoblast cells and the host vasculature. Biomaterials, 31:6959. 2010.
45.
MartineauL., DoillonC.J.Angiogenic response of endothelial cells seeded dispersed versus on beads in fibrin gels. Angiogenesis, 10:269. 2007.
46.
KorffT., AugustinH.G.Integration of endothelial cells in multicellular spheroids prevents apoptosis and induces differentiation. J Cell Biol, 143:1341. 1998.
47.
CrisanM., YapS., CasteillaL., ChenC.W., CorselliM., ParkT.S.et al.A perivascular origin for mesenchymal stem cells in multiple human organs. Cell Stem Cell, 3:301. 2008.
48.
TraktuevD.O., Merfeld-ClaussS., LiJ., KoloninM., ArapW., PasqualiniR.et al.A population of multipotent CD34-positive adipose stromal cells share pericyte and mesenchymal surface markers, reside in a periendothelial location, and stabilize endothelial networks. Circ Res, 102:77. 2008.
49.
VerseijdenF., Posthumus-van SluijsS.J., PavljasevicP., HoferS.O., van OschG.J., FarrellE.Adult human bone marrow- and adipose tissue-derived stromal cells support the formation of prevascular-like structures from endothelial cells in vitro. Tissue Eng Part A, 16:101. 2010.
50.
BellowsC.G., HeerscheJ.N., AubinJ.E.Inorganic phosphate added exogenously or released from beta-glycerophosphate initiates mineralization of osteoid nodules in vitro. Bone Miner, 17:15. 1992.
51.
Di MarcoG.S., HausbergM., HillebrandU., RustemeyerP., WittkowskiW., LangD.et al.Increased inorganic phosphate induces human endothelial cell apoptosis in vitro. Am J Physiol Renal Physiol, 294:F1381. 2008.
52.
MaesC., KobayashiT., SeligM.K., TorrekensS., RothS.I., MackemS.et al.Osteoblast precursors, but not mature osteoblasts, move into developing and fractured bones along with invading blood vessels. Dev Cell, 19:329. 2010.
KinnerB., SpectorM.Expression of smooth muscle actin in osteoblasts in human bone. J Orthop Res, 20:622. 2002.
60.
SchmittJ.M., HwangK., WinnS.R., HollingerJ.O.Bone morphogenetic proteins: an update on basic biology and clinical relevance. J Orthop Res, 17:269. 1999.
61.
DeckersM.M., van BezooijenR.L., van der HorstG., HoogendamJ., van Der BentC., PapapoulosS.E.et al.Bone morphogenetic proteins stimulate angiogenesis through osteoblast-derived vascular endothelial growth factor A. Endocrinology, 143:1545. 2002.
62.
Czarkowska-PaczekB., BartlomiejczykI., PrzybylskiJ.The serum levels of growth factors: PDGF, TGF-beta and VEGF are increased after strenuous physical exercise. J Physiol Pharmacol, 57:189. 2006.
CarrageeE.J., HurwitzE.L., WeinerB.K.A critical review of recombinant human bone morphogenetic protein-2 trials in spinal surgery: emerging safety concerns and lessons learned. Spine J, 11:471. 2011.
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