Micro and nanotechnology in vascular regeneration

Tissue and Organ Regeneration: Advances in Micro- and Nanotechnology

Volumn , Issue , 2014, Pages 695-724

  Lee, Vivian ^a   Dai, Guohao ^a  

^a RENSSELAER POLYTECHNIC INSTITUTE   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

BLOOD VESSELS; CAPILLARITY; CARDIOVASCULAR SYSTEM; DIFFUSION; HISTOLOGY; MICROCIRCULATION; NANOTECHNOLOGY; NUTRIENTS; OXYGEN; TISSUE ENGINEERING; TISSUE REGENERATION;

CARTILAGE REPLACEMENTS; DIFFERENT LENGTH SCALE; EXTRACELLULAR MATRICES; PERFUSION BIOREACTOR; TISSUE ENGINEERED CONSTRUCTS; TISSUE ENGINEERED PRODUCTS; TISSUE ENGINEERED VASCULAR GRAFTS; VASCULARIZED TISSUES;

TISSUE;

EID: 84974533847     PISSN: None     EISSN: None     Source Type: Book    
DOI: 10.4032/9789814411684     Document Type: Chapter

References (125)

1. Andrae, J., Gallini, R., and Betsholtz, C. (2008). Role of plateletderived growth factors in physiology and medicine. Genes Dev, 22: 1276-1312.
2. Asakawa, N., Shimizu, T., Tsuda, Y., Sekiya, S., Sasagawa, T., Yamato, M., Fukai, F., and Okano, T. (2010). Pre-vascularization of in vitro three-dimensional tissues created by cell sheet engineering. Biomaterials, 31: 3903-3909.
3. Badylak, S. F., Taylor, D., and Uygun, K. (2011). Whole-organ tissue engineering: decellularization and recellularization of threedimensional matrix scaffolds. Annu Rev Biomed Eng, 13: 27-53.
4. Barron, J. A., Wu, P., Ladouceur, H. D., and Ringeisen, B. R. (2004). Biological laser printing: a novel technique for creating heterogeneous 3-dimensional cell patterns. Biomed Microdevices, 6: 139-147.
5. Bel, A., Planat-Bernard, V., Saito, A., Bonnevie, L., Bellamy, V., Sabbah, L., Bellabas, L., Brinon, B., Vanneaux, V., Pradeau, P., et al. (2010). Composite cell sheets: a further step toward safe and effective myocardial regeneration by cardiac progenitors derived from embryonic stem cells. Circulation, 122: S118-S123.
6. Bettinger, C., Weinberg, E., Kulig, K., Vacanti, J., Wang, Y., Borenstein, J., and Langer, R. (2006). Three-dimensional microfluidic tissueengineering scaffolds using a flexible biodegradable polymer. Adv Mater, 18: 165-169.
7. Borenstein, J., Terai, H., King, K., Weinberg, E., Kaazempur-Mofrad, M., and Vacanti, J. (2002). Microfabrication technology for vascularized tissue engineering. Biomed Microdevices, 4: 167-175.
8. Borenstein, J. T., Tupper, M. M., Mack, P. J., Weinberg, E. J., Khalil, A. S., Hsiao, J., and García-Cardeña, G. (2010). Functional endothelialized microvascular networks with circular cross-sections in a tissue culture substrate. Biomed Microdevices, 12: 71-79.
9. Borenstein, J. T., Weinberg, E. J., Orrick, B. K., Sundback, C., Kaazempur-Mofrad, M. R., and Vacanti, J. P. (2007). Microfabrication of three-dimensional engineered scaffolds. Tissue Eng, 13: 1837-1844.
10. Carmeliet, P. (2003). Angiogenesis in health and disease. Nat Med, 9: 653-660.
11. Carmeliet, P., and Jain, R. K. (2011). Molecular mechanisms and clinical applications of angiogenesis. Nature, 473: 298-307.
12. Carrion, B., Huang, C. P., Ghajar, C. M., Kachgal, S., Kniazeva, E., Jeon, N. L., and Putnam, A. J. (2010). Recreating the perivascular niche ex vivo using a microfluidic approach. Biotechnol Bioeng, 107: 1020-1028.
13. Chiu, L. L., and Radisic, M. (2010). Scaffolds with covalently immobilized VEGF and Angiopoietin-1 for vascularization of engineered tissues. Biomaterials, 31: 226-241.
14. Chrobak, K. M., Potter, D. R., and Tien, J. (2006). Formation of perfused, functional microvascular tubes in vitro. Microvasc Res, 71: 185-196.
15. Chung, B. G., Lee, K. H., Khademhosseini, A., and Lee, S. H. (2012). Microfluidic fabrication of microengineered hydrogels and their application in tissue engineering. Lab Chip, 12: 45-59.
16. Chung, S., Sudo, R., Mack, P. J., Wan, C.-R., Vickerman, V., and Kamm, R. D. (2009). Cell migration into scaffolds under co-culture conditions in a microfluidic platform. Lab Chip, 9: 269-275.
17. Cui, X., and Boland, T. (2009). Human microvasculature fabrication using thermal inkjet printing technology. Biomaterials, 30: 6221-6227.
18. Du, Y., Ghodousi, M., Qi, H., Haas, N., Xiao, W., and Khademhosseini, A. (2011). Sequential assembly of cell-laden hydrogel constructs to engineer vascular-like microchannels. Biotechnol Bioeng, 108: 1693-1703.
19. Du, Y., Lo, E., Ali, S., and Khademhosseini, A. (2008). Directed assembly of cell-laden microgels for fabrication of 3D tissue constructs. Proc Natl Acad Sci USA, 105: 9522-9527.
20. Elloumi-Hannachi, I., Yamato, M., and Okano, T. (2010). Cell sheet engineering: a unique nanotechnology for scaffold-free tissue reconstruction with clinical applications in regenerative medicine. J Intern Med, 267: 54-70.
21. Farsari, M., and Chichkov, B. (2009). Materials processing: two-photon fabrication. Nat. Photon, 3: 450.
22. Fedorovich, N. E., Swennen, I., Girones, J., Moroni, L., van Blitterswijk, C. A., Schacht, E., Alblas, J., and Dhert, W. J. (2009). Evaluation of photocrosslinked Lutrol hydrogel for tissue printing applications. Biomacromolecules, 10: 1689-1696.
23. Fidkowski, C., Kaazempur-Mofrad, M. R., Borenstein, J., Vacanti, J. P., Langer, R., and Wang, Y. (2005). Endothelialized microvasculature based on a biodegradable elastomer. Tissue Eng, 11: 302-309.
24. Fiedler, U., and Augustin, H. G. (2006). Angiopoietins: a link between angiogenesis and inflammation. Trends Immunol, 27: 552-558.
25. Folkman, J., and Hochberg, M. (1973). Self-regulation of growth in three dimensions. J Exp Med, 138: 745-753.
26. Fuchs, S., Ghanaati, S., Orth, C., Barbeck, M., Kolbe, M., Hofmann, A., Eblenkamp, M., Gomes, M., Reis, R. L., and Kirkpatrick, C. J. (2009). Contribution of outgrowth endothelial cells from human peripheral blood on in vivo vascularization of bone tissue engineered constructs based on starch polycaprolactone scaffolds. Biomaterials, 30: 526-534.
27. Gaebel, R., Ma, N., Liu, J., Guan, J., Koch, L., Klopsch, C., Gruene, M., Toelk, A., Wang, W., Mark, P., et al. (2011). Patterning human stem cells and endothelial cells with laser printing for cardiac regeneration. Biomaterials, 32: 9218-9230.
28. Giordano, R. A., Wu, B. M., Borland, S. W., Cima, L. G., Sachs, E. M., and Cima, M. J. (1996). Mechanical properties of dense polylactic acid structures fabricated by three dimensional printing. J Biomater Sci Polym Ed, 8: 63-75.
29. Golden, A. P., and Tien, J. (2007). Fabrication of microfluidic hydrogels using molded gelatin as a sacrificial element. Lab Chip, 7: 720-725.
30. Griffith, L. G., and Naughton, G. (2002). Tissue engineering-current challenges and expanding opportunities. Science, 295: 1009-1014.
31. Griffith, L. G., and Swartz, M. A. (2006). Capturing complex 3D tissue physiology in vitro. Nat Rev Mol Cell Biol, 7: 211-224.
32. Gruene, M., Deiwick, A., Koch, L., Schlie, S., Unger, C., Hofmann, N., Bernemann, I., Glasmacher, B., and Chichkov, B. (2010). Laser printing of stem cells for biofabrication of scaffold-free autologous grafts. Tissue Eng Part C Methods, 17: 79-87.
33. Guillotin, B., Souquet, A., Catros, S., Duocastella, M., Pippenger, B., Bellance, S., Bareille, R., Rémy, M., Bordenave, L., Amédée, J., et al. (2010). Laser assisted bioprinting of engineered tissue with high cell density and microscale organization. Biomaterials, 31: 7250-7256.
34. Hamada, Y., Nokihara, K., Okazaki, M., Fujitani, W., Matsumoto, T., Matsuo, M., Umakoshi, Y., Takahashi, J., and Matsuura, N. (2003). Angiogenic activity of osteopontin-derived peptide SVVYGLR. Biochem Biophys Res Commun, 310: 153-157.
35. Harris, J. D., Siston, R. A., Pan, X., and Flanigan, D. C. (2010). Autologous chondrocyte implantation: a systematic review. J Bone Joint Surg Am, 92: 2220-2233.
36. Harrison, B. S., Eberli, D., Lee, S. J., Atala, A., and Yoo, J. J. (2007). Oxygen producing biomaterials for tissue regeneration. Biomaterials, 28: 4628-4634.
37. Hersel, U., Dahmen, C., and Kessler, H. (2003). RGD modified polymers: biomaterials for stimulated cell adhesion and beyond. Biomaterials, 24: 4385-4415.
38. Hobo, K., Shimizu, T., Sekine, H., Shińoka, T., Okano, T., and Kurosawa, H. (2008). Therapeutic angiogenesis using tissue engineered human smooth muscle cell sheets. Arterioscler Thromb Vasc Biol, 28: 637-643.
39. Hoganson, D. M., Pryor, H. I., Spool, I. D., Burns, O. H., Gilmore, J. R., and Vacanti, J. P. (2010). Principles of biomimetic vascular network design applied to a tissue-engineered liver scaffold. Tissue Eng Part A, 16: 1469-1477.
40. Hollister, S. J. (2005). Porous scaffold design for tissue engineering. Nat Mater, 4: 518-524.
41. Hu, J., Sun, X., Ma, H., Xie, C., Chen, Y. E., and Ma, P. X. (2010). Porous nanofibrous PLLA scaffolds for vascular tissue engineering. Biomaterials, 31: 7971-7977.
42. Hubbell, J. A., Massia, S. P., Desai, N. P., and Drumheller, P. D. (1991). Endothelial cell-selective materials for tissue engineering in the vascular graft via a new receptor. Biotechnology (NY), 9: 568-572.
43. Hutmacher, D. W., Sittinger, M., and Risbud, M. V. (2004). Scaffold-based tissue engineering: rationale for computer-aided design and solid free-form fabrication systems. Trends Biotechnol, 22: 354-362.
44. Jain, R. K. (2003). Molecular regulation of vessel maturation. Nat Med, 9: 685-693.
45. Janssen, F. W., Oostra, J., Oorschot, A., and van Blitterswijk, C. A. (2006). A perfusion bioreactor system capable of producing clinically relevant volumes of tissue-engineered bone: in vivo bone formation showing proof of concept. Biomaterials, 27: 315-323.
46. Kelm, J. M., Lorber, V., Snedeker, J. G., Schmidt, D., Broggini-Tenzer, A., Weisstanner, M., Odermatt, B., Mol, A., Zünd, G., and Hoerstrup, S. P. (2010). A novel concept for scaffold-free vessel tissue engineering: self-assembly of microtissue building blocks. J Biotechnol, 148: 46-55.
47. Keriquel, V., Guillemot, F., Arnault, I., Guillotin, B., Miraux, S., Amédée, J., Fricain, J.-C., and Catros, S. (2010). In vivo bioprinting for computerand robotic-assisted medical intervention: preliminary study in mice. Biofabrication, 2: 014101.
48. Khademhosseini, A., Vacanti, J. P., and Langer, R. (2009). Progress in tissue engineering. Sci Am, 300: 64-71.
49. Khan, O. F., Chamberlain, M. D., and Sefton, M. V. (2012). Toward an in vitro vasculature: differentiation of mesenchymal stromal cells within an endothelial cell-seeded modular construct in a microfluidic flow chamber. Tissue Eng Part A, 18: 744-756.
50. Kim, K., Ohashi, K., Utoh, R., Kano, K., and Okano, T. (2012). Preserved liver-specific functions of hepatocytes in 3D co-culture with endothelial cell sheets. Biomaterials, 33: 1406-1413.
51. Landers, R., Hübner, U., Schmelzeisen, R., and Mülhaupt, R. (2002). Rapid prototyping of scaffolds derived from thermoreversible hydrogels and tailored for applications in tissue engineering. Biomaterials, 23: 4437-4447.
52. Lee, S.-H., Moon, J. J., and West, J. L. (2008). Three-dimensional micropatterning of bioactive hydrogels via two-photon laser scanning photolithography for guided 3D cell migration. Biomaterials, 29: 2962-2968.
53. Leong, M. F., Rasheed, M. Z., Lim, T. C., and Chian, K. S. (2009). In vitro cell infiltration and in vivo cell infiltration and vascularization in a fibrous, highly porous poly(D,L-lactide) scaffold fabricated by cryogenic electrospinning technique. J Biomed Mater Res A, 91: 231-240.
54. Leslie-Barbick, J. E., Shen, C., Chen, C., and West, J. L. (2011). Micronscale spatially patterned, covalently immobilized vascular endothelial growth factor on hydrogels accelerates endothelial tubulogenesis and increases cellular angiogenic responses. Tissue Eng Part A, 17: 221-229.
55. Li, J., Wei, Y., Liu, K., Yuan, C., Tang, Y., Quan, Q., Chen, P., Wang, W., Hu, H., and Yang, L. (2010). Synergistic effects of FGF-2 and PDGF-BB on angiogenesis and muscle regeneration in rabbit hindlimb ischemia model. Microvasc Res, 80: 10-17.
56. Lin, C. Y., Kikuchi, N., and Hollister, S. J. (2004). A novel method for biomaterial scaffold internal architecture design to match bone elastic properties with desired porosity. J Biomech, 37: 623-636.
57. Liu Tsang, V., Chen, A. A., Cho, L. M., Jadin, K. D., Sah, R. L., DeLong, S., West, J. L., and Bhatia, S. N. (2007). Fabrication of 3D hepatic tissues by additive photopatterning of cellular hydrogels. FASEB J, 21: 790-801.
58. Loffredo, F., and Lee, R. T. (2008). Therapeutic vasculogenesis: it takes two. Circ Res, 103: 128-130.
59. Lovett, M., Lee, K., Edwards, A., and Kaplan, D. L. (2009). Vascularization strategies for tissue engineering. Tissue Eng Part B Rev, 15: 353-370.
60. Lutolf, M. P., Lauer-Fields, J. L., Schmoekel, H. G., Metters, A. T., Weber, F. E., Fields, G. B., and Hubbell, J. A. (2003). Synthetic matrix metalloproteinase-sensitive hydrogels for the conduction of tissue regeneration: engineering cell-invasion characteristics. Proc Natl Acad Sci USA, 100: 5413-5418.
61. Ma, P. X. (2008). Biomimetic materials for tissue engineering. Adv Drug Deliv Rev, 60: 184-198.
62. MacNeil, S. (2007). Progress and opportunities for tissue-engineered skin. Nature, 445: 874-880.
63. Masumoto, H., Matsuo, T., Yamamizu, K., Uosaki, H., Narazaki, G., Katayama, S., Marui, A., Shimizu, T., Ikeda, T., Okano, T., et al. (2012). Pluripotent stem cell-engineered cell sheets reassembled with defined cardiovascular populations ameliorate reduction in infarct heart function through cardiomyocyte-mediated neovascularization. Stem Cells, 30: 1196-1205.
64. McGuigan, A. P., and Sefton, M. V. (2006). Vascularized organoid engineered by modular assembly enables blood perfusion. Proc Natl Acad Sci USA, 103: 11461-11466.
65. Melero-Martin, J. M., De Obaldia, M. E., Kang, S.-Y., Khan, Z. A., Yuan, L., Oettgen, P., and Bischoff, J. (2008). Engineering robust and functional vascular networks in vivo with human adult and cord blood-derived progenitor cells. Circ Res, 103: 194-202.
66. Miller, J. S., Shen, C. J., Legant, W. R., Baranski, J. D., Blakely, B. L., and Chen, C. S. (2010). Bioactive hydrogels made from step-growth derived PEG-peptide macromers. Biomaterials, 31: 3736-3743.
67. Mironov, V., Boland, T., Trusk, T., Forgacs, G., and Markwald, R. R. (2003). Organ printing: computer-aided jet-based 3D tissue engineering. Trends Biotechnol, 21: 157-161.
68. Mironov, V., Visconti, R. P., Kasyanov, V., Forgacs, G., Drake, C. J., and Markwald, R. R. (2009). Organ printing: tissue spheroids as building blocks. Biomaterials, 30: 2164-2174.
69. Miyagi, Y., Chiu, L. L., Cimini, M., Weisel, R. D., Radisic, M., and Li, R. K. (2011). Biodegradable collagen patch with covalently immobilized VEGF for myocardial repair. Biomaterials, 32: 1280-1290.
70. Moon, J. J., Hahn, M. S., Kim, I., Nsiah, B. A., and West, J. L. (2009). Micropatterning of poly(ethylene glycol) diacrylate hydrogels with biomolecules to regulate and guide endothelial morphogenesis. Tissue Eng Part A, 15: 579-585.
71. Moon, J. J., Saik, J. E., Poché, R. A., Leslie-Barbick, J. E., Lee, S.-H., Smith, A. A., Dickinson, M. E., and West, J. L. (2010). Biomimetic hydrogels with pro-angiogenic properties. Biomaterials, 31: 3840-3847.
72. Nillesen, S. T., Geutjes, P. J., Wismans, R., Schalkwijk, J., Daamen, W. F., and van Kuppevelt, T. H. (2007). Increased angiogenesis and blood vessel maturation in acellular collagen-heparin scaffolds containing both FGF2 and VEGF. Biomaterials, 28: 1123-1131.
73. Norotte, C., Marga, F. S., Niklason, L. E., and Forgacs, G. (2009). Scaffoldfree vascular tissue engineering using bioprinting. Biomaterials, 30: 5910-5917.
74. Oh, S. H., Ward, C. L., Atala, A., Yoo, J. J., and Harrison, B. S. (2009). Oxygen generating scaffolds for enhancing engineered tissue survival. Biomaterials, 30: 757-762.
75. Ohashi, K., Yokoyama, T., Yamato, M., Kuge, H., Kanehiro, H., Tsutsumi, M., Amanuma, T., Iwata, H., Yang, J., Okano, T., et al. (2007). Engineering functional two- and three-dimensional liver systems in vivo using hepatic tissue sheets. Nat Med, 13: 880-885.
76. Ott, H. C., Matthiesen, T. S., Goh, S.-K., Black, L. D., Kren, S. M., Netoff, T. I., and Taylor, D. A. (2008). Perfusion-decellularized matrix: using nature's platform to engineer a bioartificial heart. Nat Med, 14: 213-221.
77. Ovsianikov, A., Malinauskas, M., Schlie, S., Chichkov, B., Gittard, S., Narayan, R., Löbler, M., Sternberg, K., Schmitz, K.-P., and Haverich, A. (2011). Three-dimensional laser micro- and nano-structuring of acrylated poly(ethylene glycol) materials and evaluation of their cytoxicity for tissue engineering applications. Acta Biomater, 7: 967-974.
78. Parzel, C. A., Pepper, M. E., Burg, T., Groff, R. E., and Burg, K. J. L. (2009). EDTA enhances high-throughput two-dimensional bioprinting by inhibiting salt scaling and cell aggregation at the nozzle surface. J Tissue Eng Regen Med, 3: 260-268.
79. Peirce, S. M., Price, R. J., and Skalak, T. C. (2004). Spatial and temporal control of angiogenesis and arterialization using focal applications of VEGF164 and Ang-1. Am J Physiol Heart Circ Physiol, 286: H918-H925.
80. Peltola, S. M., Melchels, F. P., Grijpma, D. W., and Kellomaki, M. (2008). A review of rapid prototyping techniques for tissue engineering purposes. Ann Med, 40: 268-280.
81. Petersen, T. H., Calle, E. A., Zhao, L., Lee, E. J., Gui, L., Raredon, M. B., Gavrilov, K., Yi, T., Zhuang, Z. W., Breuer, C., et al. (2010). Tissue-engineered lungs for in vivo implantation. Science, 329: 538-541.
82. Pham, Q. P., Sharma, U., and Mikos, A. G. (2006). Electrospinning of polymeric nanofibers for tissue engineering applications: a review. Tissue Eng, 12: 1197-1211.
83. Phelps, E. A., and Garcia, A. J. (2010). Engineering more than a cell: vascularization strategies in tissue engineering. Curr Opin Biotechnol, 21: 704-709.
84. Phelps, E. A., Landázuri, N., Thulé, P. M., Taylor, W. R., and García, A. J. (2010). Bioartificial matrices for therapeutic vascularization. Proc Natl Acad Sci USA, 107: 3323-3328.
85. Portner, R., Nagel-Heyer, S., Goepfert, C., Adamietz, P., and Meenen, N. M. (2005). Bioreactor design for tissue engineering. J Biosci Bioeng, 100: 235-245.
86. Raeber, G. P., Lutolf, M. P., and Hubbell, J. A. (2005). Molecularly engineered PEG hydrogels: a novel model system for proteolytically mediated cell migration. Biophys J, 89: 1374-1388.
87. Raghavan, S., Nelson, C. M., Baranski, J. D., Lim, E., and Chen, C. S. (2010). Geometrically controlled endothelial tubulogenesis in micropatterned gels. Tissue Eng Part A, 16: 2255-2263.
88. Roth, E. A., Xu, T., Das, M., Gregory, C., Hickman, J. J., and Boland, T. (2004). Inkjet printing for high-throughput cell patterning. Biomaterials, 25: 3707-3715.
89. Rouwkema, J., Rivron, N. C., and van Blitterswijk, C. A. (2008). Vascularization in tissue engineering. Trends Biotechnol, 26: 434-441.
90. Saik, J. E., Gould, D. J., Watkins, E. M., Dickinson, M. E., and West, J. L. (2011). Covalently immobilized platelet-derived growth factor-BB promotes angiogenesis in biomimetic poly(ethylene glycol) hydrogels. Acta Biomater, 7: 133-143.
91. Santos, M. I., Tuzlakoglu, K., Fuchs, S., Gomes, M. E., Peters, K., Unger, R. E., Piskin, E., Reis, R. L., and Kirkpatrick, C. J. (2008). Endothelial cell colonization and angiogenic potential of combined nano- and micro-fibrous scaffolds for bone tissue engineering. Biomaterials, 29: 4306-4313.
92. Saunders, R. E., Gough, J. E., and Derby, B. (2008). Delivery of human fibroblast cells by piezoelectric drop-on-demand inkjet printing. Biomaterials, 29: 193-203.
93. Schiele, N. R., Corr, D. T., Huang, Y., Raof, N. A., Xie, Y., and Chrisey, D. B. (2010). Laser-based direct-write techniques for cell printing. Biofabrication, 2: 032001.
94. Sefcik, L. S., Petrie Aronin, C. E., Wieghaus, K. A., and Botchwey, E. A. (2008). Sustained release of sphingosine 1-phosphate for therapeutic arteriogenesis and bone tissue engineering. Biomaterials, 29: 2869-2877.
95. Sekine, H., Shimizu, T., Hobo, K., Sekiya, S., Yang, J., Yamato, M., Kurosawa, H., Kobayashi, E., and Okano, T. (2008). Endothelial cell coculture within tissue-engineered cardiomyocyte sheets enhances neovascularization and improves cardiac function of ischemic hearts. Circulation, 118: S145-S152.
96. Sekiya, S., Muraoka, M., Sasagawa, T., Shimizu, T., Yamato, M., and Okano, T. (2010). Three-dimensional cell-dense constructs containing endothelial cell-networks are an effective tool for in vivo and in vitro vascular biology research. Microvasc Res, 80: 549-551.
97. Shin, H., Jo, S., and Mikos, A. G. (2003). Biomimetic materials for tissue engineering. Biomaterials, 24: 4353-4364.
98. Shin, Y., Jeon, J. S., Han, S., Jung, G.-S., Shin, S., Lee, S.-H., Sudo, R., Kamm, R. D., and Chung, S. (2011). In vitro 3D collective sprouting angiogenesis under orchestrated ANG-1 and VEGF gradients. Lab Chip, 11: 2175-2181.
99. Sill, T. J., and von Recum, H. A. (2008). Electrospinning: applications in drug delivery and tissue engineering. Biomaterials, 29: 1989-2006.
100. Singh, M., Berkland, C., and Detamore, M. S. (2008). Strategies and applications for incorporating physical and chemical signal gradients in tissue engineering. Tissue Eng Part B Rev, 14: 341-366.
101. Skardal, A., Zhang, J., and Prestwich, G. D. (2010). Bioprinting vessel-like constructs using hyaluronan hydrogels crosslinked with tetrahedral polyethylene glycol tetracrylates. Biomaterials, 31: 6173-6181.
102. Sreejalekshmi, K. G., and Nair, P. D. (2011). Biomimeticity in tissue engineering scaffolds through synthetic peptide modifications-altering chemistry for enhanced biological response. J Biomed Mater Res A, 96: 477-491.
103. Sudo, R., Chung, S., Zervantonakis, I. K., Vickerman, V., Toshimitsu, Y., Griffith, L. G., and Kamm, R. D. (2009). Transport-mediated angiogenesis in 3D epithelial coculture. FASEB J, 23: 2155-2164.
104. Sun, G., Shen, Y.-I., Kusuma, S., Fox-Talbot, K., Steenbergen, C. J., and Gerecht, S. (2011). Functional neovascularization of biodegradable dextran hydrogels with multiple angiogenic growth factors. Biomaterials, 32: 95-106.
105. Sun, W., Darling, A., Starly, B., and Nam, J. (2004). Computer-aided tissue engineering: overview, scope and challenges. Biotechnol Appl Biochem, 39: 29-47.
106. Tayalia, P., and Mooney, D. (2009). Controlled Growth Factor Delivery for Tissue Engineering. Adv. Mater., 21.
107. Tengood, J.E., Ridenour, R., Brodsky, R., Russell, A.J., and Little, S.R. (2011). Sequential delivery of basic fibroblast growth factor and platelet-derived growth factor for angiogenesis. Tissue Eng Part A, 17: 1181-1189.
108. Vavken, P., and Samartzis, D. (2010). Effectiveness of autologous chondrocyte implantation in cartilage repair of the knee: a systematic review of controlled trials. Osteoarthritis Cartilage, 18: 857-863.
109. Vickerman, V., Blundo, J., Chung, S., and Kamm, R. (2008). Design, fabrication and implementation of a novel multi-parameter control microfluidic platform for three-dimensional cell culture and real-time imaging. Lab Chip, 8: 1468-1477.
110. von der Mark, K., Park, J., Bauer, S., and Schmuki, P. (2010). Nanoscale engineering of biomimetic surfaces: cues from the extracellular matrix. Cell Tissue Res, 339: 131-153.
111. Wang, Z.Z., Au, P., Chen, T., Shao, Y., Daheron, L.M., Bai, H., Arzigian, M., Fukumura, D., Jain, R.K., and Scadden, D.T. (2007). Endothelial cells derived from human embryonic stem cells form durable blood vessels in vivo. Nat Biotechnol, 25: 317-318.
112. Whitesides, G.M., Ostuni, E., Takayama, S., Jiang, X., and Ingber, D.E. (2001). Soft lithography in biology and biochemistry. Annu Rev Biomed Eng, 3: 335-373.
113. Wieghaus, K.A., Capitosti, S.M., Anderson, C.R., Price, R.J., Blackman, B.R., Brown, M.L., and Botchwey, E.A. (2006). Small molecule inducers of angiogenesis for tissue engineering. Tissue Eng, 12: 1903-1913.
114. Wu, P.K., and Ringeisen, B.R. (2010). Development of human umbilical vein endothelial cell (HUVEC) and human umbilical vein smooth muscle cell (HUVSMC) branch/stem structures on hydrogel layers via biological laser printing (BioLP). Biofabrication, 2: 014111.
115. Xu, T., Jin, J., Gregory, C., Hickman, J.J., and Boland, T. (2005). Inkjet printing of viable mammalian cells. Biomaterials, 26: 93-99.
116. Yang, F., Cho, S., Son, S., Bogatyrev, S., Singh, D., Green, J., Mei, Y., Park, S., Bhang, S., Kim, B., et al. (2009). Regenerative Medicine Special Feature: Genetic engineering of human stem cells for enhanced angiogenesis using biodegradable polymeric nanoparticles. Proc Natl Acad Sci USA.
117. Yang, J., Yamato, M., Shimizu, T., Sekine, H., Ohashi, K., Kanzaki, M., Ohki, T., Nishida, K., and Okano, T. (2007). Reconstruction of functional tissues with cell sheet engineering. Biomaterials, 28: 5033-5043.
118. Yang, S., Leong, K.F., Du, Z., and Chua, C.K. (2002). The design of scaffolds for use in tissue engineering. Part II. Rapid prototyping techniques. Tissue Eng, 8: 1-11.
119. Yee, D., Hanjaya-Putra, D., Bose, V., Luong, E., and Gerecht, S. (2011). Hyaluronic Acid hydrogels support cord-like structures from endothelial colony-forming cells. Tissue Eng Part A, 17: 1351-1361.
120. Yeong, W.-Y., Chua, C.-K., Leong, K.-F., and Chandrasekaran, M. (2004). Rapid prototyping in tissue engineering: challenges and potential. Trends Biotechnol, 22: 643-652.
121. Yoon, J.J., Chung, H.J., Lee, H.J., and Park, T.G. (2006). Heparinimmobilized biodegradable scaffolds for local and sustained release of angiogenic growth factor. J Biomed Mater Res A, 79: 934-942.
122. Yoon, J.J., Chung, H.J., and Park, T.G. (2007). Photo-crosslinkable and biodegradable Pluronic/heparin hydrogels for local and sustained delivery of angiogenic growth factor. J Biomed Mater Res A, 83: 597-605.
123. Yuen, W.W., Du, N.R., Chan, C.H., Silva, E.A., and Mooney, D.J. (2010). Mimicking nature by codelivery of stimulant and inhibitor to create temporally stable and spatially restricted angiogenic zones. Proc Natl Acad Sci USA, 107: 17933-17938.
124. Zhao, L., Lee, V.K., Yoo, S.-S., Dai, G., and Intes, X. (2012). The integration of 3-D cell printing and mesoscopic fluorescence molecular tomography of vascular constructs within thick hydrogel scaffolds. Biomaterials, 33: 5325-5332.
125. Zheng, Y., Henderson, P.W., Choi, N.W., Bonassar, L.J., Spector, J.A., and Stroock, A.D. (2011). Microstructured templates for directed growth and vascularization of soft tissue in vivo. Biomaterials, 32: 5391-5401.