A combined tissue engineering dynamic culture apparatus

doi:10.3877/cma.j.issn.1673-9450.2018.03.004

Abstract

Abstract:

With the diverse application of tissue engineering technology, increasingly related researches got attention of scholars, including providing different culture condition for different target tissue to improve their histochemical and biomechanical properties or induce specific differentiation of stem cells. Combined with the existing laboratory conditions of China, Plastic Surgery Hospital, Chinese Academy of Medical Sciences, Peking Union Medical College has invented this combined tissue engineering dynamic culture apparatus, aiming to provide different dynamic culture conditions for various engineered tissue.

Key words: Tissue culture techniques, Tissue engineering, Patents, Dynamic culture

Xiaona Lu, Yihao Xu, Huan Wang, Jianjun You, Bo Zhang, Ruobing Zheng, Le Tian, Fei Fan. A combined tissue engineering dynamic culture apparatus[J]. Chinese Journal of Injury Repair and Wound Healing(Electronic Edition), 2018, 13(03): 172-175.

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https://zhssyxfzz.cma-cmc.com.cn/EN/Y2018/V13/I03/172

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References 20

[1]	Barba M, Di Taranto G, Lattanzi W. Adipose-derived stem cell therapies for bone regeneration[J]. Expert Opin Biol Ther, 2017, 17(6):677-689.
[2]	Shah AR, Cornejo A, Guda T, et al. Differentiated adipose-derived stem cell cocultures for bone regeneration in polymer scaffolds in vivo[J]. J Craniofac Surg, 2014, 25(4):1504-1509.
[3]	Dai NT, Fan GY, Liou NH, et al. Histochemical and functional improvement of adipose-derived stem cell-based tissue-engineered cartilage by hyperbaric oxygen/air treatment in a rabbit articular defect model[J]. Ann Plast Surg, 2015, 74 Suppl 2:S139-145.
[4]	Jeong CG, Zhang H, Hollister SJ. Three-dimensional polycaprolactone scaffold-conjugated bone morphogenetic protein-2 promotes cartilage regeneration from primary chondrocytes in vitro and in vivo without accelerated endochondral ossification[J]. J Biomed Mater Res A, 2012, 100(8):2088-2096.
[5]	Lau TT, Lee LQ, Vo BN, et al. Inducing ossification in an engineered 3D scaffold-free living cartilage template[J]. Biomaterials, 2012, 33(33):8406-8417.
[6]	Gemmiti CV, Guldberg RE. Fluid flow increases type II collagen deposition and tensile mechanical properties in bioreactor-grown tissue-engineered cartilage[J]. Tissue Eng, 2006, 12(3):469-479.
[7]	Green WT Jr. Articular cartilage repair. Behavior of rabbit chondrocytes during tissue culture and subsequent allografting[J]. Clin Orthop Relat Res, 1977(124):237-250.
[8]	Vacanti CA, Langer R, Schloo B, et al. Synthetic polymers seeded with chondrocytes provide a template for new cartilage formation[J]. Plast Reconstr Surg, 1991, 88(5):753-759.
[9]	Wakitani S, Imoto K, Kimura T, et al. Hepatocyte growth factor facilitates cartilage repair. Full thickness articular cartilage defect studied in rabbit knees[J]. Acta Orthop Scand, 1997, 68(5):474-480.
[10]	Wakitani S, Goto T, Pineda SJ, et al. Mesenchymal cell-based repair of large, full-thickness defects of articular cartilage[J]. J Bone aJoint Surg Am, 1994, 76(4):579-592.
[11]	Cao Y, Vacanti JP, Paige KT, et al. Transplantation of chondrocytes utilizing a polymer-cell construct to produce tissue-engineered cartilage in the shape of a human ear[J]. Plast Reconstr Surg, 1997, 100(2):297-302; discussion 303-304.
[12]	Griffin MF, Szarko M, Seifailan A, et al. Nanoscale Surface Modifications of Medical Implants for Cartilage Tissue Repair and Regeneration[J]. Open Orthop J, 2016, 10:824-835.
[13]	Jacobs NT, Cortes DH, Peloquin JM, et al. Validation and application of an intervertebral disc finite element model utilizing independently constructed tissue-level constitutive formulations that are nonlinear, anisotropic, and time-dependent[J]. J Biomech, 2014, 47(11):2540-2546.
[14]	Guo LX, Li R, Zhang M. Biomechanical and fluid flowing characteristics of intervertebral disc of lumbar spine predicted by poroelastic finite element method[J]. Acta Bioeng Biomech, 2016, 18(2):19-29.
[15]	Holmes MH, Lai WM, Mow VC. Singular perturbation analysis of the nonlinear, flow-dependent compressive stress relaxation behavior of articular cartilage[J]. J Biomech Eng, 1985, 107(3):206-218.
[16]	Griffin MF, Premakumar Y, Seifalian AM, et al. Biomechanical Characterisation of the Human Auricular Cartilages; Implications for Tissue Engineering[J]. Ann Biomed Eng, 2016, 44(12):3460-3467.
[17]	Lan Levengood SK, Polak SJ, Poellmann MJ, et al. The effect of BMP-2 on micro- and macroscale osteointegration of biphasic calcium phosphate scaffolds with multiscale porosity[J]. Acta Biomater, 2010, 6(8):3283-3291.
[18]	Wagoner Johnson AJ, Herschler BA. A review of the mechanical behavior of CaP and CaP/polymer composites for applications in bone replacement and repair[J]. Acta Biomater, 2011, 7(1):16-30.
[19]	Williams JM, Adewunmi A, Schek RM, et al. Bone tissue engineering using polycaprolactone scaffolds fabricated via selective laser sintering[J]. Biomaterials, 2005, 26(23):4817-4827.
[20]	Tarafder S, Balla VK, Davies NM, et al. Microwave-sintered 3D printed tricalcium phosphate scaffolds for bone tissue engineering[J]. J Tissue Eng Regen Med, 2013, 7(8):631-641.

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