The functionality of vascular networks within implanted prevascularized tissues is difficult to assess using traditional analysis techniques, such as histology. This is largely due to the inability to visualize hemodynamics in vivo longitudinally. Therefore, we have developed dynamic imaging methods to measure blood flow and hemoglobin oxygen saturation in implanted prevascularized tissues noninvasively and longitudinally. Using laser speckle imaging, multispectral imaging, and intravital microscopy, we demonstrate that fibrin-based tissue implants anastomose with the host (severe combined immunodeficient mice) in as short as 20 h. Anastomosis results in initial perfusion with highly oxygenated blood, and an increase in average hemoglobin oxygenation of 53%. However, shear rates in the preformed vessels were low (20.8±12.8 s−1), and flow did not persist in the vast majority of preformed vessels due to thrombus formation. These findings suggest that designing an appropriate vascular network structure in prevascularized tissues to maintain shear rates above the threshold for thrombosis may be necessary to maintain flow following implantation. We conclude that wide-field and microscopic functional imaging can dynamically assess blood flow and oxygenation in vivo in prevascularized tissues, and can be used to rapidly evaluate and improve prevascularization strategies.
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References
1.
CarmelietP., JainR.K.Angiogenesis in cancer and other diseases. Nature, 407:249. 2000.
2.
MuschlerG.F., NakamotoC., GriffithL.G.Engineering principles of clinical cell-based tissue engineering. J Bone Joint Surg Am, 86:1541. 2004.
3.
HelmlingerG., YuanF., DellianM., JainR.K.Interstitial pH and pO2 gradients in solid tumors in vivo: high-resolution measurements reveal a lack of correlation. Nat Med, 3:177. 1997.
NieX., CaiJ.K., YangH.M., XiaoH.A., WangJ.H., WenN., ZhangY.J., JinY.Successful application of tissue-engineered skin to refractory ulcers. Clin Exp Dermatol, 32:699. 2007.
6.
FujiharaY., AsawaY., TakatoT., HoshiK.Tissue reactions to engineered cartilage based on poly-L-lactic acid scaffolds. Tissue Eng Part A, 15:1565. 2008.
7.
HunzikerE.B.Articular cartilage repair: basic science and clinical progress. A review of the current status and prospects. Osteoarthritis Cartilage, 10:432. 2002.
8.
PeiM., HeF., BoyceB.M., KishV.L.Repair of full-thickness femoral condyle cartilage defects using allogeneic synovial cell-engineered tissue constructs. Osteoarthritis Cartilage, 17:714. 2009.
9.
RyuW., MinS.W., HammerickK.E., VyakarnamM., GrecoR.S., PrinzF.B., FaschingR.J.The construction of three-dimensional micro-fluidic scaffolds of biodegradable polymers by solvent vapor based bonding of micro-molded layers. Biomaterials, 28:1174. 2007.
10.
RichardsonT.P., PetersM.C., EnnettA.B., MooneyD.J.Polymeric system for dual growth factor delivery. Nat Biotech, 19:1029. 2001.
11.
OttH.C., MatthiesenT.S., GohS.-K., BlackL.D., KrenS.M., NetoffT.I., TaylorD.A.Perfusion-decellularized matrix: using nature's platform to engineer a bioartificial heart. Nat Med, 14:213. 2008.
12.
GilbertT.W., SellaroT.L., BadylakS.F.Decellularization of tissues and organs. Biomaterials, 27:3675. 2006.
13.
LaschkeM.W., RückerM., JensenG., CarvalhoC., MülhauptR., GellrichN.-C., MengerM.D.Improvement of vascularization of PLGA scaffolds by inosculation of in situ-preformed functional blood vessels with the host microvasculature. Ann Surg, 248:939. 2008.
ChenX., AlediaA.S., GhajarC.M., GriffithC.K., PutnamA.J., HughesC.C.W., GeorgeS.C.Prevascularization of a fibrin-based tissue construct accelerates the formation of functional anastomosis with host vasculature. Tissue Eng Part A, 15:1363. 2008.
16.
ChenX., AlediaA.S., PopsonS.A., HimL., HughesC.C.W., GeorgeS.C.Rapid anastomosis of endothelial progenitor cell–derived vessels with host vasculature is promoted by a high density of cotransplanted fibroblasts. Tissue Eng Part A, 16:585. 2010.
17.
ClarkE.R., ClarkE.L.Microscopic observations on the growth of blood capillaries in the living mammal. Am J Anat, 64:251. 1939.
18.
RouwkemaJ., RivronN.C., Van BlitterswijkC.A.Vascularization in tissue engineering. Trends Biotechnol, 26:434. 2008.
19.
RouwkemaJ., WesterweelP.E., BoerJ.D., VerhaarM.C., Van BlitterswijkC.A.The use of endothelial progenitor cells for prevascularized bone tissue engineering. Tissue Eng Part A, 15:2015. 2009.
20.
VerseijdenF., Posthumus-Van SluijsS.J., Van NeckJ.W., HoferS.O.P., HoviusS.E.R., Van OschG.J.V.M.Vascularization of prevascularized and non-prevascularized fibrin-based human adipose tissue constructs after implantation in nude mice. J Tissue Eng Regen Med, 6:169. 2012.
21.
DvirT., KedemA., RuvinovE., LevyO., FreemanI., LandaN., HolbovaR., FeinbergM.S., DrorS., EtzionY., LeorJ., CohenS.Prevascularization of cardiac patch on the omentum improves its therapeutic outcome. Proc Natl Acad Sci U S A, 106:14990. 2009.
22.
UngerR.E., GhanaatiS., OrthC., SartorisA., BarbeckM., HalstenbergS., MottaA., MigliaresiC., KirkpatrickC.J.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.
23.
NörJ.E., PetersM.C., ChristensenJ.B., SutorikM.M., LinnS., KhanM.K., AddisonC.L., MooneyD.J., PolveriniP.J.Engineering and characterization of functional human microvessels in immunodeficient mice. Lab Invest, 81:453. 2001.
SorgB.S., MoellerB.J., DonovanO., CaoY., DewhirstM.W.Hyperspectral imaging of hemoglobin saturation in tumor microvasculature and tumor hypoxia development. J Biomed Opt, 10:44004. 2005.
26.
AuP., DaheronL.M., DudaD.G., CohenK.S., TyrrellJ.A., LanningR.M., FukumuraD., ScaddenD.T., JainR.K.Differential in vivo potential of endothelial progenitor cells from human umbilical cord blood and adult peripheral blood to form functional long-lasting vessels. Blood, 111:1302. 2008.
ChoiB., KangN.M., NelsonJ.S.Laser speckle imaging for monitoring blood flow dynamics in the in vivo rodent dorsal skin fold model. Microvasc Res, 68:143. 2004.
29.
ChoiB., Ramirez-San-JuanJ.C., LotfiJ., NelsonJ.S.Linear response range characterization and in vivo application of laser speckle imaging of blood flow dynamics. J Biomed Opt, 11:041129. 2006.
30.
DunnA.K., BolayH., MoskowitzM.A., BoasD.A.Dynamic imaging of cerebral blood flow using laser speckle. J Cereb Blood Flow Metab, 21:195. 2001.
31.
PapenfussH.D., GrossJ.F., IntagliettaM., TreeseF.A.A transparent access chamber for the rat dorsal skin fold. Microvasc Res, 18:311. 1979.
32.
MoyA., WhiteS., IndrawanE., LotfiJ., NudelmanM., CostantiniS., AgarwalN., JiaW., KellyK., SorgB., ChoiB.Wide-field functional imaging of blood flow and hemoglobin oxygen saturation in the rodent dorsal window chamber. Microvasc Res, 82:199. 2011.
33.
BuiA.K., TevesK.M., IndrawanE., JiaW., ChoiB.Longitudinal, multimodal functional imaging of microvascular response to photothermal therapy. Opt Lett, 35:3216. 2010.
34.
FercherA.F., BriersJ.D.Flow visualization by means of single-exposure speckle photography. Opt Commun, 37:326. 1981.
35.
YuanS., DevorA., BoasD.A., DunnA.K.Determination of optimal exposure time for imaging of blood flow changes with laser speckle contrast imaging. Appl Optics, 44:1823. 2005.
36.
WhiteS.M., GeorgeS.C., ChoiB.Automated computation of functional vascular density using laser speckle imaging in a rodent window chamber model. Microvasc Res, 82:92. 2011.
37.
KirkpatrickS.J., DuncanD.D., Wells-GrayE.M.Detrimental effects of speckle-pixel size matching in laser speckle contrast imaging. J Biomed Opt, 33:2886. 2008.
38.
Ramirez-San-JuanJ.C., Ramos-GarcíaR., Guizar-IturbideI., Martínez-NiconoffG., ChoiB.Impact of velocity distribution assumption on simplified laser speckle imaging equation. Opt Express, 16:3197. 2008.
39.
ShonatR.D., WachmanE.S., NiuW., KoretskyA.P., FarkasD.L.Near-simultaneous hemoglobin saturation and oxygen tension maps in mouse brain using an AOTF microscope. Biophys J, 73:1223. 1997.
40.
RogganA., FriebelM., DörschelK., HahnA., MüllerG.Optical properties of circulating human blood in the wavelength range 400–2500 nm. J Biomed Opt, 4. 1999.
SchafferC.B., FriedmanB., NishimuraN., SchroederL.F., TsaiP.S., EbnerF.F., LydenP.D., KleinfeldD.Two-photon imaging of cortical surface microvessels reveals a robust redistribution in blood flow after vascular occlusion. PLoS Biol, 4:258. 2006.
43.
KamounW.S., ChaeS.-S., LacorreD.A., TyrrellJ.A., MitreM., GillissenM.A., FukumuraD., JainR.K., MunnL.L.Simultaneous measurement of RBC velocity, flux, hematocrit and shear rate in vascular networks. Nat Meth, 7:655. 2010.
44.
LiuJ., BarradasA., FernandesH., JanssenF., PapenburgB., StamatialisD., MartensA., BlitterswijkC.V., BoerJ.D.In vitro and in vivo bioluminescent imaging of hypoxia in tissue-engineered grafts. Tissue Eng Part C, 16:479. 2010.
45.
AppelA., AnastasioM.A., BreyE.M.Potential for imaging engineered tissues with X-ray phase contrast. Tissue Eng Part B, 17:321. 2011.
46.
ZimmermannW.-H., MelnychenkoI., WasmeierG., DidieM., NaitoH., NixdorffU., HessA., BudinskyL., BruneK., MichaelisB., DheinS., SchwoererA., EhmkeH., EschenhagenT.Engineered heart tissue grafts improve systolic and diastolic function in infarcted rat hearts. Nat Med, 12:452. 2006.
47.
FarajK.A., CuijpersV.M.J.I., WismansR.G., WalboomersX.F., JansenJohn A., KuppeveltT.H.V., DaamenW.F.Micro-computed tomographical imaging of soft biological materials using contrast techniques. Tissue Eng Part C, 15:493. 2009.
48.
McdonaldD.M., ChoykeP.L.Imaging of angiogenesis: from microscope to clinic. Nat Med, 9:713. 2003.
49.
Melero-MartinJ.M., KhanZ.A., PicardA., WuX., ParuchuriS., BischoffJ.In vivo vasculogenic potential of human blood-derived endothelial progenitor cells. Blood, 109:4761. 2007.
50.
IngramD.A., CapliceN.M., YoderM.C.Unresolved questions, changing definitions, and novel paradigms for defining endothelial progenitor cells. Blood, 106:1525. 2005.
51.
BenjaminL.E., HemoI., KeshetE.A plasticity window for blood vessel remodelling is defined by pericyte coverage of the preformed endothelial network and is regulated by PDGF-B and VEGF. Development, 125:1591. 1998.
FarbA., BurkeA.P., KolodgieF.D., VirmaniR.Pathological mechanisms of fatal late coronary stent thrombosis in humans. Circulation, 108:1701. 2003.
55.
ShenF., KastrupC.J., LiuY., IsmagilovR.F.Threshold response of initiation of blood coagulation by tissue factor in patterned microfluidic capillaries is controlled by shear rate. Arterioscl Throm Vas, 28:2035. 2008.
56.
EckmannD.M., BowersS., SteckerM., CheungA.T.Hematocrit, volume expander, temperature, and shear rate effects on blood viscosity. Anesth Analg, 91:539. 2000.
57.
ChienS.Shear dependence of effective cell volume as a determinant of blood viscosity. Science, 168:977. 1970.
58.
MurrayC.D.The physiological principle of minimum work. I. The vascular system and the cost of blood volume. Proc Natl Acad Sci U S A, 12:207. 1926.
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