1.
Daly W, Yao L, Zeugolis D, et al. A biomaterials approach to peripheral regeneration: bridging the peripheral nerve gap and enhancing functional recovery. J R Soc Interface. 2012;9:202–221.
2.
Seddon H. Three types of nerve injury. Brain. 1943;66:237–288.
3.
Sunderland S. A classification of peripheral nerve injuries producing loss of function. Brain. 1951;74:491–516.
4.
Campbell WW. Evaluation and management of peripheral nerve injury. Clin Neurophysiol. 2008;119:1951–1965.
5.
Deumens R, Bozkurt A, Meek MF, et al. Repairing injured peripheral nerves: bridging the gap. Prog Neurobiol. 2010;92:245–276.
6.
Millessi H. Techniques for nerve grafting. Hand Clin. 2000;16:73–91.
7.
Kehoe S, Zhang XF, Boyd D. FDA approved guidance conduits and wraps for peripheral nerve injury: a review of materials and efficacy. Injury. 2012;43:553–572.
8.
Siemionow M, Brzezicki G. Chapter 8: current, techniques and concepts in peripheral nerve repair. In: Stefano G, Pierluigi T, Bruno B, editors. International Review of Neurobiology. San Diego, CA: Academic Press; 2009:141–172.
9.
Nichols CM, Brenner MJ, Fox IK, et al. Effects of motor versus sensory nerve grafts on peripheral nerve regeneration. Exp Neurol. 2004;190:347–355.
10.
Siemionow M, Sonmez E. Nerve Allograft transplantation: a review. J Reconstr Microsurg. 2007;23(8):511–520.
11.
Hebebrand D, Zohman G, Jones NF. Nerve xenograft transplantation: immunosuppression with FK-506 and RS-61443. Biomaterials. 1997;22(3):304–307.
12.
Jia HJ, Wang Y, Tong XJ, et al. Sciatic nerve repair by acellular nerve xenografts implanted with BMSCs in rats xenograft combined with BMSCs. Synapse. 2012;66:256–269.
13.
Mackinnon S, Hudson A, Falk R, Bilbao J, Kline D, Hunter D. Nerve allograft response: a quantitative immunological study. Neurosurgery. 1982;10:61–69.
14.
Mackinnon SE, Doolabh VB, Novak CB, Trulock EP. Clinical outcome following nerve allograft transplantation. Plast Reconstr Surg. 2001;107:1419–1429.
15.
Hudson TW, Liu SY, Schmidt CE. Engineering an improved acellular nerve graft via optimized chemical processing. Tissue Eng. 2004;10:1346–1358.
16.
Gilbert TW, Sellaro TL, Badylak SF. Decellularization of tissues and organs. Biomaterials. 2006;27(19):3675–3683.
17.
Gulati AK. Evaluation of acellular and cellular nerve grafts in repair of rat peripheral nerve. J Neurosurg. 1988;68:117–123.
18.
Freytes DO, Badylak SF, Webster TJ, et al. Biaxial strength of multilaminated extracellular matrix scaffolds. Biomaterials. 2004;25:2353–2361.
19.
Lin P, Chan WC, Badylak SF, et al. Assessing porcine liver-derived biomatrix for hepatic tissue engineering. Tissue Eng. 2004;10:1046–1053.
20.
Yoo JJ, Meng J, Oberpenning F, et al. Bladder augmentation using allogenic bladder submucosa seeded with cells. Urology. 1998;51:221–225.
21.
De Filippo RE, Yoo JJ, Atala A. Urethral replacement using cell seeded tubularized collagen matrices. J Urol. 2002;168:1789–1792.
22.
Dahl SL, Koh J, Prabhakar V, et al. Decellularized native and engineered arterial scaffolds for transplantation. Cell Transplant. 2003;12:659–666.
23.
Chen RN, Ho HO, Tsai YT, et al. Process development of an acellular dermal matrix (ADM) for biomedical applications. Biomaterials. 2004;25(13):2679–2686.
24.
Woods T, Gratzer PF. Effectiveness of three extraction techniques in the development of a decellularized bone–anterior cruciate ligament–bone graft. Biomaterials. 2005;26:7339–7349.
25.
Vyavahare N, Hirsch D, Lerner E, et al. Prevention of bioprosthetic heart valve calcification by ethanol preincubation. Efficacy and mechanisms. Circulation. 1997;95:479–488.
26.
Goissis G, Suzigan S, Parreira DR, et al. Preparation and characterization of collagen–elastin matrices from blood vessels intended as small diameter vascular grafts. Artif Organs. 2000;24:217–223.
27.
Courtman DW, Pereira CA, Kashef V, et al. Development of a pericardial acellular matrix biomaterial: biochemical and mechanical effects of cell extraction. J Biomed Mater Res. 1994;28:655–666.
28.
Rieder E, Kasimir MT, Silberhumer G, et al. Decellularization protocols of porcine heart valves differ importantly in efficiency of cell removal and susceptibility of the matrix to recellularization with human vascular cells. J Thorac Cardiovasc Surg. 2004;127:399–405.
29.
Gamba PG, Conconi MT, Lo Piccolo R, et al. Experimental abdominal wall defect repaired with acellular matrix. Pediatr Surg Int. 2002;18:327–331.
30.
Clark JN, Ogle MF, Ashworth P, et al. Prevention of calcification of bioprosthetic heart valve cusp and aortic wall with ethanol and aluminium chloride. Ann Thorac Surg. 2005;79(3):897–904.
31.
Frerichs O, Fansa H, Schicht C, Wolf G, Schneider W, Keilhoff G. Reconstruction of peripheral nerves using acellular nerve grafts with implanted cultured Schwann cells. Microsurgery. 2002;22(7):311–315.
32.
Krekoski CA, Neubauer D, Graham JB, et al. Metalloproteinase-dependent predegeneration in vitro enhances axonal regeneration within acellular peripheral nerve grafts. J Neurosci. 2002;22(23):10408–10415.
33.
Kim BS, Yoo JJ, Atala A. Peripheral nerve regeneration using acellular nerve grafts. J Biomed Mater Res A. 2004;68(2):201–209.
34.
Neubauer D, Graham JB, Muir D. Chondroitinase treatment increases the effective length of acellular nerve grafts. Exp Neurol. 2007;207:163–170.
35.
Whitlock EL, Tuffaha SH, Luciano JP, et al. Processed allografts and type I collagen conduits for repair of peripheral nerve gaps. Muscle Nerve. 2009;39:787–799.
36.
Sun F, Zhou K, Mi WJ, et al. Combined use of decellularized allogeneic artery conduits with autologous transdifferentiated adipose-derived stem cells for facial nerve regeneration in rats. Biomaterials. 2011;32(32):8118–8128.
37.
Zhao Z, Wnag Y, Peng J, et al. Improvement in nerve regeneration through a decellularized nerve graft by supplementation with bone marrow stromal cells in fibrin. Cell Transplant. 2014;23(1):97–110.
38.
Gluck T. Ueber Transplantation, Regeneration und entzündliche Neubildung. Klin Wochenschr. 1881;18:554–557.
39.
Lundborg G. A 25-year perspective of peripheral nerve surgery: evolving neuroscientific concepts and clinical significance. J Hand Surg. 2000;25:391–414.
40.
Verreck G, Chun I, Li Y, et al. Preparation and physico-chemical characterization of biodegradable nerve guides containing the nerve growth agent sabeluzole. Biomaterials. 2005;26:1307–1315.
41.
Freed LE, Vunjak-Novakovic G, Biron RJ, et al. Biodegradable polymer scaffolds for tissue engineering. Nat Biotechnol. 1994;12:689–693.
42.
Schmidt CE, Leach JB. Neural tissue engineering: strategies for repair and regeneration. Annu Rev Biomed Eng. 2003;5:293–347.
43.
Hrabak O. Industrial production of poly-3-hydroxybutyrate. FEMS Microbiol Rev. 1992;103:251–256.
44.
Williams SF, Martin DP, Horowitz DM, Peoples OP. PHA applications: addressing the price performance issue: I. Tissue engineering. Int J Biol Macromol. 1999;25:111–121.
45.
Hazari A, Johansson-Rudén G, Junemo-Bostrom K, et al. A new resorbable wrap-around implant as an alternative nerve repair technique. J Hand Surg Br. 1999;24:291–295.
46.
Aberg M, Ljungberg C, Edin E, et al. Clinical evaluation of a resorbable wrap-around implant as an alternative to nerve repair: a prospective, assessor-blinded, randomised clinical study of sensory, motor and functional recovery after peripheral nerve repair. J Plast Reconstr Aesthet Surg. 2009;62:1503–1509.
47.
Terenghi G, Mosahebi A. The interface between peripheral axons, Schwann cells and biosynthetic nerve guides. In: Aldskogius H, Fraher J, editors. Glial Interfaces in the Nervous System: Role in Repair and Plasticity. Amsterdam: IOS Press; 2002:13–20.
48.
Armstrong SJ, Wiberg M, Terenghi G, et al. ECM molecules mediate both Schwann cell proliferation and activation to enhance neurite outgrowth. Tissue Eng. 2007;13(12):2863–2870.
49.
Mohanna PN, Young RC, Wiberg M, et al. A composite poly-hydroxybutyrate–glial growth factor conduit for long nerve gap repairs. J Anat. 2003;203:553–565.
50.
Erba P, Mantovani C, Kalbermatten DF, et al. Regeneration potential and survival of transplanted undifferentiated adipose tissue-derived stem cells in peripheral nerve conduits. J Plast Reconstr Aes. 2010;63(12):e811–e817.
51.
Masaeli E, Morshed M, Nasr-Esfahani MH, et al. Fabrication, characterization and cellular compatibility of poly(hydroxy alkanoate) composite nanofibrous scaffolds for nerve tissue engineering. PloS One. 2013;8(2):e57157.
52.
Biazar E, Heidari KH. A nanofibrous phbv tube with Schwann cell as artificial nerve graft contributing to rat sciatic nerve regeneration across a 30-mm defect bridge. Cell Commun Adhes. 2013;20(1–2):41–49.
53.
Biazar E, Keshel SH. Chitosan–cross-linked nanofibrous PHBV nerve guide for rat sciatic nerve regeneration across a defect bridge. ASAIO J. 2013;56(6):651–659.
54.
Prabhakaran MP, Atankhan E, Ramakrishna S. Electrospun aligned PHBV/collagen nanofibers as substrates for nerve tissue engineering. Biotechnol Bioeng. 2013;110(10):2775–2784.
55.
Kadler KE, Holmes DE, Trotter JA, et al. Collagen fibril formation. Biochem J. 1996;316:1–11.
56.
Evans DG, Baser ME, McGaughran J, Sharif S, Howard E, Moran A. Malignant peripheral nerve sheath tumours in neurofibromatosis 1. J Med Genet. 2002;39:311–314.
57.
Brown RA, Phillips JB. Cell responses to biomimetic protein scaffolds used in tissue repair and engineering. Int Rev Cytol. 2007;262:75–150.
58.
Brown RA, Wiseman M, Chuo C-B, Cheema U, Nazhat SN. Ultrarapid engineering of biomimetic materials and tissues: fabrication of nano- and microstructures by plastic compression. Adv Funct Mater. 2005;15:1762–1770.
59.
Archibald S, Krarup C, Shefner J, et al. A collagen-based nerve guide conduit for peripheral nerve repair: an electrophysiological study of nerve regeneration in rodents and nonhuman primates. J Comp Neurol. 1991;306:685–696.
60.
Mackinnon SE, Hudson AR, Bojanowski V, Hunter DA, Maraghi E. Peripheral-nerve injection injury with purified bovine collagen – an experimental-model in the rat. Ann Plast Surg. 1985;14:428–436.
61.
Meek MF, Coert JH. US Food and Drug Administration/Conformit Europe–approved absorbable nerve conduits for clinical repair of peripheral and cranial nerves. Ann Plast Surg. 2008;60:466–472.
62.
Kramer BA, Kader Ag, Klark RN. Use of the Neuro-Wrap system for severe post-electroconvulsive therapy headaches. J ECT. 2008;24(2):152–155.
63.
Li ST, Yuen D, inventors; Collagen Matrix, Inc., assignee. Implant devices for nerve repair. United States patent US6716225 B2. April 6, 2004.
64.
Li ST, Archibald SJ, Krarup C, Madison RD. Peripheral nerve repair with collagen conduits. Clin Mater. 1992;9:195–200.
65.
Lohmeyer JA, Siemers F, Machens HG, et al. The clinical use of artificial nerve conduits for digital nerve repair: a prospective cohort study and literature review. J Reconstr Microsurg. 2009;25:55–61.
66.
Madduri S, Feldman K, Tervoort T. Collagen nerve conduits releasing the neurotrophic factors GDNF and NGF. J Controlled Release. 2010;143:168–174.
67.
Yang CR, Chen JD. Preparation and biological evaluation of chitosan–collagen–icariin composite scaffolds for neuronal regeneration. Neurol Sci. 2013;34:941–947.
68.
Salvatore L, Madaghiele M, Parisi C, Gatti F, Sannino A. Crosslinking of micropatterned collagen based nerve guides to modulate the expected half life. J Biomed Mater Res A. Epub February 14, 2014.
69.
Liu BS, Yao CH, Hsu SH, et al. A novel use of genipin-fixed gelatin as extracellular matrix for peripheral nerve regeneration. J Biomater Appl. 2004;19:21–34.
70.
Cenni E, Ciapetti G, Stea S, et al. Biocompatibility and performance in vitro of a hemostatic gelatin sponge. J Biomater Sci Polym Ed. 2000;11:685–699.
71.
Gamez E, Goto Y, Nagata K, Iwaki T, Sasaki T, Matsuda. Photofabricated gelatin-based nerve conduits: nerve tissue regeneration potential. Cell Transplant. 2004;13(5):549–564.
72.
Chen YS, Chang JY, Chen CY, et al. An in vivo evaluation of a biodegradable genipin-cross-linked gelatin peripheral nerve guide conduit material. Biomaterials. 2005;26:3911–3918.
73.
Liu BS. Fabrication and evaluation of a biodegradable proanthocyanidin-crosslinked gelatin conduit in peripheral nerve repair. J Biomed Mater Res A. 2008;15;87(4):1092–1102.
74.
Nie X, Deng M, Yang M, Liu L, Zhang Y, Wen X. Axonal regeneration and remyelination evaluation of chitosan/gelatin based nerve guide combined with transforming growth factor-β1 and Schwann cells. Cell Biochen Biophys. 2014;68:163–172.
75.
Whitworth IH, Terenghi G, Green CJ, et al. Targeted delivery of nerve growth factor via fibronectin conduits assists nerve regeneration in control and diabetic rats. Eur J Neurosci. 1995;7:2220–2225.
76.
Whitworth IH, Brown RA, Dore CJ, et al. Nerve growth factor enhances nerve regeneration through fibronectin grafts. J Hand Surg. 1996;21B:514–522.
77.
Ahmed Z, Brown RA. Adhesion, alignment and migration of cultured Schwann cells on ulrathin fibronectin fibres. Cell Motil Cytoskel. 1999;42:331–343.
78.
Phillips JB, Bunting SCJ, Ward Z, Hall SM, Brown RA. Fibronectin tubes as tissue engineering devices for peripheral nerve repair. Molecular, Cellular and Tissue Engineering, 2002. Proceedings of the IEEE-EMBS Special Topic Conference.
79.
Mosahebi A, Wiberg M, Terenghi G. Addition of fibronectin to alginate matrix improves peripheral nerve regeneration in tissue-engineered conduits. Tissue Eng. 2009;9(2):209–218.
80.
Ding T, Lu WW, Zheng Y, Li Zy, Pan Hb, Luo Z. Rapid repair of rat sciatic nerve injury using a nanosilver-embedded collagen scaffold coated with laminin and fibronectin. Regen Med. 2011;6(4):437–447.
81.
Kaplan DL, Mello SM, Arcidiacono S, et al. In: McGrath KKD, editor. Protein Based Materials. Boston: Birkhauser; 1998:103–131.
82.
Bini E, Knight DP, Kaplan DL. Mapping domain structures in silks from insects and spiders related to protein assembly. J Mol Biol. 2004;335(1):27–40.
83.
Yang Y, Chen X, Ding F, et al. Biocompatibility evaluation of silk fibroin with peripheral nerve tissues and cells in vitro. Biomaterials. 2007;28:1643–1652.
84.
Huang W, Begum R, Barber T, et al. Regenerative potential of silk conduits in repair of peripheral nerve injury in adult rats. Biomaterials. 2012;33:59–71.
85.
Gu Y, Zhu J, Xue C, et al. Chitosan/silk fibroin-based, Schwann cell-derived extracellular matrix-modified scaffolds for bridging rat sciatic nerve gaps. Biomaterials. 2014;35(7):2253–2263.
86.
Schacht K, Scheibel T. Processing of recombinant spider silk proteins into tailor-made materials for biomaterials applicayions. Curr Opin Biotech. 2014;29C:62–69.
87.
Crewther WG, Fraser RDB, Lennox FG, Lindley H. The chemistry of keratins. In: Anfinsen CB Jr, Anson ML, Edsall JT, Richards FM, editors. Advances in Protein Chemistry. New York: Academic Press; 1965:191–346.
88.
Lin YC, Ramadan M, Van Dyke M, et al. Keratin gel filler for peripheral nerve repair in a rodent sciatic nerve injury model. Plast Reconstr Surg. 2012;129(1):67–78.
89.
Pace LA, Plate JF, Mannava S, et al. A human hair keratin hydrogel scaffold enhances median nerve regeneration in nonhuman primates: an electrophysiological and histological study. Tissue Eng Part A. 2014;20(3–4):507–517.
90.
Sierpinski P, Garrett J, Ma J, et al. The use of keratin biomaterials derived from human hair for the promotion of rapid regeneration of peripheral nerves. Biomaterials. 2008;29(1):118–128.
91.
Nishinari K, Takahashi R. Interaction in polysaccharide solutions and gels. Curr Opin Colloid Interface Sci. 2003;8:396–400.
92.
Yu L, Dean K, Li L. Polymer blends and composites from renewable resources. Prog Polym Sci. 2006;31:576–602.
93.
Eugene K, Lee YL. Implantable applications of chitin and chitosan. Biomaterials. 2003;24:2339–2349.
94.
Zheng L, Cui HF. Use of chitosan conduit combined with bone marrow mesenchymal stem cells for promoting peripheral nerve regeneration. J Mater Sci Mater Med. 2010;21(5);1713–1720.
95.
Haastert-Talini K, Geuna S, Dahlin LB, et al. Chitosan tubes of varying degrees of acetylation for bridging peripheral nerve defects. Biomaterials. 2013;34(38):9886–9904.
96.
Carvalho CR, Correia MA, Oliveire JM, Reis RL. Chitosan nanofibers as scaffolds for peripheral nerve regeneration. J Tissue Eng Reg Med. 2013;7(Supp 1):6–52.
97.
Hsu SH, Kuo WC, Chen YT, et al. New nerve regeneration strategy combining laminin-coated chitosan conduits and stem cell therapy. Acta Biomater. 2013;9(5):6606–6615.
98.
Burdick AJ, Prestwich GD. Hyaluronic acid hydrogels for biomedical applications. Adv Mater. 2011;23(12):H41–H56.
99.
Suri S, Schmidt CR. Cell-laden hydrogel constructs of hyaluronic acid, collagen, and laminin for neural tissue engineering. Tissue Eng Part A. 2010;16(5):1707–1713.
100.
Guan S, Zhang XL, Lin XM, Liu TQ, Ma XH, Cui ZF. Chitosan/gelatin porous scaffolds containing hyaluronic acid and heparan sulfate for neural tissue engineering. J Biomater Sci Polym Ed. 2013;24(8):999–1014.
101.
Tian B, Liu J, Dvir T, et al. Macroporous nanowire nanoelectronic scaffolds for synthetic tissues. Nat Mater. 2012;11:986–994.
102.
Lu MC, Huang YT, Lin JH, et al. Evaluation of a multi-layer microbraided polylactic acid fiber-reinforced conduit for peripheral nerve regeneration. J Mater Sci Mater Med. 2009;20:1175–1180.
103.
Hsu SH, Chan SH, Chiang CM, et al. Peripheral nerve regeneration using a microporous polylactic acid asymmetric conduit in a rabbit long-gap sciatic nerve transection model. Biomaterials. 2011;32:3764–3775.
104.
Matsumine H, Sasaki R, Yamato M, Okano T, Sakurai H. A polylactic acid non-woven nerve conduit for facial nerve regeneration in rats. J Tissue Eng Regen Med. 2014;8(6):454–462.
105.
Ni HC, Tseng TC, Chen JR, Hsu SH, Chiu IM. Fabrication of bioactive conduits containing the fibroblast growth factor 1 and neural stem cells for peripheral nerve regeneration across a 15 mm critical gap. Biofabrication. 2013;5:035010.
106.
Evans GRD, Brandt K, Widmer MS, et al. In vivo evaluation of poly(L-lactic acid) porous conduits for peripheral nerve regeneration. Biomaterials. 1999;20:1109–1115.
107.
Rutkowski GE, Miller CA, Jeftinija S, Mallapragada SK. Synergistic effects of micropatterned biodegradable conduits and Schwann cells on sciatic nerve regeneration. J Neural Eng. 2004;1:151–157.
108.
Li J, McNally H, Shi R. Enhanced neurite alignment on micro-patterned poly-L-lactic acid films. J Biomed Mater Res Part A. 2008; 87:392–404.
109.
Liu JJ, Wang CY, Wang JG, et al. Peripheral nerve regeneration using composite poly(lactic acid-caprolactone)/nerve growth factor conduits prepared by coaxial electrospinning. J Biomed Mater Res Part A. 2011;96:1–20.
110.
Xu H, Holzwarth JM, Yan Y, et al. Conductive PPY/PDLLA conduit for peripheral nerve regeneration. Biomaterials. 2014;35:225–235.
111.
Tabesh H, Amoabediny G, Nik NS, et al. The role of biodegradable engineered scaffolds seeded with Schwann cells for spinal cord regeneration. Neurochem Int. 2009;54:73–83.
112.
Dellon AL, Chang BW. An alternative incision for approaching recurrent median nerve compression at the wrist. Plast Reconstr Surg. 1992;89:576–578.
113.
Costa HJZR, Bento RF, Salomone R, et al. Mesenchymal bone marrow stem cells within polyglycolic acid tube observed in vivo after six weeks enhance facial nerve regeneration. Brain Res. 2013;1510:10–21.
114.
Sundback C, Hadlock T, Cheney M, et al. Manufacture of porous polymer nerve conduits by a novel low-pressure injection molding process. Biomaterials. 2003;24:819–830.
115.
Yang Y, De Laporte L, Rives CB, et al. Neurotrophin releasing single and multiple lumen nerve conduits. J Control Release. 2005;104:433–446.
116.
Wen X, Tresco PA. Fabrication and characterization of permeable degradable poly(DL-lactide-co-glycolide) (PLGA) hollow fiber phase inversion membranes for use as nerve tract guidance channels. Biomaterials. 2006;27:3800–3809.
117.
Oh SH, Kim JH, Song KS, et al. Peripheral nerve regeneration within an asymmetrically porous PLGA/Pluronic F127 nerve guide conduit. Biomaterials. 2008;29:1601–1609.
118.
Lee JY, Bashur CA, Goldstein AS, et al. Polypyrrole-coated electrospun PLGA nanofibers for neural tissue applications. Biomaterials. 2009;30:4325–4335.
119.
Shen H, Shen ZL, Zhang PH, et al. Ciliary neurotrophic factor-coated polylactic-polyglycolic acid chitosan nerve conduit promotes peripheral nerve regeneration in canine tibial nerve defect repair. J Biomed Mater Res B Appl Biomater. 2010;95:161–170.
120.
Daly WT, Knight AM, Wang H, et al. Comparison and characterization of multiple biomaterial conduits for peripheral nerve repair. Biomaterials. 2013;34:8630–8639.
121.
Sun M, Kingham PJ, Reid AJ, et al. In vitro and in vivo testing of novel ultra thin PCL and PCL/PLA blend films as peripheral nerve conduit. J Biomed Mater Res Part A. 2010;93:1470–1481.
122.
Oliveira JT, Almeida FM, Biancalana A, et al. Mesenchymal stem cells in a polycaprolactone conduit enhance median-nerve regeneration, prevent decrease of creatine phosphokinase levels in muscle, and improve functional recovery in mice. Neuroscience. 2010;170:1295–1303.
123.
Moroder P, Runge MB, Wang H, et al. Material properties and electrical stimulation regimens of polycaprolactone fumarate-polypyrrole scaffolds as potential conductive nerve conduits. Acta Biomater. 2011;7:944–953.
124.
Rui J, Dadsetan M, Runge MB, et al. Controlled release of vascular endothelial growth factor using poly-lactic-co-glycolic acid microspheres: in vitro characterization and application in polycaprolactone fumarate nerve conduits. Acta Biomater. 2012;8:511–518.
125.
Frattini F, Lopes FRP, Almeida FM, et al. Mesenchymal stem cells in a polycaprolactone conduit promote sciatic nerve regeneration and sensory neuron survival after nerve injury. Tissue Eng Part A. 2012;18:2030–2039.
126.
Mobasseri SA, Terenghi G, Downes S. Micro-structural geometry of thin films intended for the inner lumen of nerve conduits affects nerve repair. J Mater Sci Mater Med. 2013;24(7):1639–1647.
127.
Kim JR, Oh SH, Kwon GB, et al. Acceleration of peripheral nerve regeneration through asymmetrically porous nerve guide conduit applied with biological/physical stimulation. Tissue Eng Part A. 2013;19:2674–2685.
128.
Radulescu D, Dhar S, Young CM, et al. Tissue engineering scaffolds for nerve regeneration manufactured by ink-jet technology. Mater Sci Eng C. 2007;27:534–539.
129.
McConnell MP, Dhar S, Nguyen T, et al. Nerve growth factor expression response to induction agent booster dosing in transfected human embryonic kidney cells. Plast Reconstr Surg. 2005;115(2):506–514.
130.
Chiriac S, Facca S, Diaconu M, et al. Experience of using the bioresorbable copolyester poly(DL-lactide-ε-caprolactone) nerve conduit guide Neurolac™ for nerve repair in peripheral nerve defects: report on a series of 28 lesions. J Hand Surg Eur. 2011;37:342–349.
131.
Yin D, Wang X, Yan Y, Zhang R. Preliminary studies on peripheral nerve regeneration using a new polyurethane conduit. J Bioact Compat Polym. 2007;22:143–159.
132.
Niu Y, Chen KC, He T, et al. Scaffolds from block polyurethanes based on poly(3-caprolactone) (PCL) and poly(ethylene glycol) (PEG) for peripheral nerve regeneration. Biomaterials. 2014;35:4266–4277.
133.
Rutkowski GE, Heath CA. Development of a bioartificial nerve graft. II. Nerve regeneration in vitro. Biotechnol Prog. 2002;18:373–379.
134.
Shokrgozar MA, Mottaghitalab F, Mottaghitalab V, et al. Fabrication of porous chitosan/poly(vinyl alcohol) reinforced single-walled carbon nanotube nanocomposites for neural tissue engineering. J Biomed Nanotechnol. 2011;7:1–9.
135.
Alhosseini SN, Moztarzadeh F, Mozafari M, et al. Synthesis and characterization of electrospun polyvinyl alcohol nanofibrous scaffolds modified by blending with chitosan for neural tissue engineering. Int J Nanomed. 2012;7:25–34.
136.
Bergethon PR, Trinkaus-Randall V, Franzblau C. Modified hydroxyethylmethacrylate hydrogels as a modelling tool for the study of cell-substratum interactions. J Cell Sci. 1989;92:111–121.
137.
Lee J, Cuddihy MJ, Kotov NA. Three-dimensional cell culture matrices: state of the art. Tissue Eng Part B. 2008;14:61–86.
138.
Dhoot NO, Tobias CA, Fischer I, et al. Peptide-modified alginate surfaces as a growth permissive substrate for neur-ite outgrowth. J Biomed Mater Res. 2004;71A:191–200.
139.
Yu TT, Shoichet MS. Guided cell adhesion and outgrowth in peptide-modified channels for neural tissue engineering. Biomaterials. 2005;26:1507–1514.
140.
Gupta D, Tator CH, Shoichet MS. Fast-gelling injectable blend of hyaluronan and methylcellulosefor intrathecal, localized delivery to the injured spinal cord. Biomaterials. 2006:27:2370–2379.
141.
Wang X, Cui T, Yan Y, Zhang R. Peroneal nerve regeneration using a unique bilayer polyurethane-collagen guide conduit. J Bioact Compat Polym. 2009;24(2):109–127.
142.
Xu H, Yan Y, Li S. PDLLA/chondroitin sulfate/chitosan/NGF conduits for peripheral nerve regeneration. Biomaterials. 2011;32:4506–4515.
143.
Lee BK, Ju YM, Cho JG, et al. End-to-side neurorrhaphy using an electrospun PCL/collagen nerve conduit for complex peripheral motor nerve regeneration. Biomaterials. 2012;33:9027–9036.
144.
Yucel D, Torun Kose G, Hasirci V. Polyester based nerve guidance conduit design. Biomaterials. 2010;31(7):1596–1603.
145.
Yucel D, Torun Kose G, Hasirci V. Tissue engineered, guided nerve tube consisting of aligned neural stem cells and astrocytes. Biomacromolecules. 2010;11:3584–3591.
146.
Cooper A, Bhattarai N, Zhang M. Fabrication and cellular compatibility of aligned chitosan–PCL fibers for nerve tissue regeneration. Carbohydr Polym. 2011;85(1):149–156.
147.
Kiyotani T, Teramachi M, Takimoto Y, et al. Nerve regeneration across a 25-mm gap bridged by a polyglycolic acid-collagen tube: a histological and electrophysiological evaluation of regenerated nerves. Brain Res. 1996;740:66–74.
148.
Matsumato K, Ohnishi K, Kiyotani T, et al. Peripheral nerve regeneration across an 80-mm gap bridged by a polyglycolic acid (PGA)-collagen tube filled with laminin-coated collagen fibers: a histological and electrophysiological evaluation of regenerated nerves. Brain Res. 2000;868:315–328.
149.
Toba T, Nakamura T, Shimizu Y, et al. Regeneration of canine peroneal nerve with the use of a polyglycolic acid-collagen tube filled with laminin-soaked collagen sponge: a comparative study of collagen sponge and collagen fibers as filling materials for nerve conduits. J Biomed Mater Res. 2001;58:622–630.
150.
Nakamura T, Inada Y, Fukuda S, et al. Experimental study on the regeneration of peripheral nerve gaps through a polyglycolic acid-collagen (PGA-collagen) tube. Brain Res. 2004;1027:18–29.