A flow perfusion bioreactor with controlled mechanical stimulation: Application in cartilage tissue engineering and beyond
Article Sidebar
Main Article Content
Abstract
To repair articular cartilage (AC) defects in osteoarthritic patients, one approach is to engineer three-dimensional grafts with physicochemical properties similar to endogenous AC. Such grafts can be grown in bioreactors that provide environmental conditions favoring chondrogenesis. Studies show mechanical stimulation during the culturing process greatly enhances development of functional engineered grafts. A review of literature on bioreactor options reveals a lack of capacity to simultaneously stimulate cells with a combination of shear stress and oscillating hydrostatic pressure, both of which are important parts of the in vivo AC environment. It is hypothesized that combining both forces in a new bioreactor design will contribute to better AC tissue growth. In this paper, we provide a brief review of bioreactors and describe a new computer-controlled perfusion and pressurized bioreactor system, and the novelty of its control programming features for service in a host of applications. We briefly summarize results on synergistic effects in employing perfusion, oscillating hydrostatic pressure in a scaffold free environment and with the addition of encapsulation for inducing chondrogenesis. We further describe efforts to modify the newly developed system to include a continuous flow and pressurized centrifugal mode to enhance further the capabilities for inclusion of very high shear stresses. Applications for several other cell and tissue engineering approaches are discussed.
Article Details
Copyright (c) 2018 Nazempour A, et al.
This work is licensed under a Creative Commons Attribution 4.0 International License.
The Journal of Stem Cell Therapy and Transplantation is committed in making it easier for people to share and build upon the work of others while maintaining consistency with the rules of copyright. In order to use the Open Access paradigm to the maximum extent in true terms as free of charge online access along with usage right, we grant usage rights through the use of specific Creative Commons license.
License: Copyright © 2017 - 2025 | 
Open Access by Journal of Stem Cell Therapy and Transplantation is licensed under a Creative Commons Attribution 4.0 International License. Based on a work at Heighten Science Publications Inc.
With this license, the authors are allowed that after publishing with the journal, they can share their research by posting a free draft copy of their article to any repository or website.
Compliance 'CC BY' license helps in:
| Permission to read and download | ✓ |
| Permission to display in a repository | ✓ |
| Permission to translate | ✓ |
| Commercial uses of manuscript | ✓ |
'CC' stands for Creative Commons license. 'BY' symbolizes that users have provided attribution to the creator that the published manuscripts can be used or shared. This license allows for redistribution, commercial and non-commercial, as long as it is passed along unchanged and in whole, with credit to the author.
Please take in notification that Creative Commons user licenses are non-revocable. We recommend authors to check if their funding body requires a specific license.
Fecek C, Yao D, Kaçorri A, Vasquez A, Iqbal S, et al. Chondrogenic derivatives of embryonic stem cells seeded into 3D polycaprolactone scaffolds generated cartilage tissue in vivo. Tissue Eng Part A. 2008; 14: 1403-1413. Ref.: https://tinyurl.com/y7mc2myh
Chang Q, Cui WD, Fan WM. Co-culture of chondrocytes and bone marrow mesenchymal stem cells in vitro enhances the expression of cartilaginous extracellular matrix components. Braz J Med Biol Res. 2011; 44: 303-310. Ref.: https://tinyurl.com/yakcnrf8
Mobasheri A, Vannucci SJ, Bondy CA, Carter SD, Innes JF, et al. Glucose transport and metabolism in chondrocytes: a key to understanding chondrogenesis, skeletal development and cartilage degradation in osteoarthritis. Histol Histopathol. 2002; 17: 1239-67. Ref.: https://tinyurl.com/y7hf92yw
Olee T, Grogan SP, Lotz MK, Colwell CW Jr, D'Lima DD, et al. Repair of Cartilage Defects in Arthritic Tissue with Differentiated Human Embryonic Stem Cells. Tissue Eng Part A. 2013; 19: 19.
Mauck RL, Soltz MA, Wang CCB, Wong DD, Chao PHG, et al. Functional tissue engineering of articular cartilage through dynamic loading of chondrocyte-seeded agarose gels. Journal of Biomechanical Engineering-Transactions of the ASME. 2000; 122: 252-260. Ref.: https://tinyurl.com/y7o5ajwz
von der Mark K, Gauss V, von der mark H, müller P. Relationship between cell shape and type of collagen synthesised as chondrocytes lose their cartilage phenotype in culture. Nature. 1977; 267: 531-532. Ref.: https://tinyurl.com/ybtqrffo
Schnabel M, Marlovits S, Eckhoff G, Fichtel I, Gotzen L, et al. Dedifferentiation-associated changes in morphology and gene expression in primary human articular chondrocytes in cell culture. Osteoarthritis Cartilage. 2002; 10: 62-70. Ref.: https://tinyurl.com/yd4e8j3m
Kim HJ, Im GI. Chondrogenic differentiation of adipose tissue-derived mesenchymal stem cells: greater doses of growth factor are necessary. J Orthop Res. 2009; 27: 612-619. Ref.: https://tinyurl.com/y84pyhee
Zhang L, Su P, Xu C, Yang J, Yu W, et al. Chondrogenic differentiation of human mesenchymal stem cells: a comparison between micromass and pellet culture systems. Biotechnology Lett. 2010; 32: 1339-1346. Ref.: https://tinyurl.com/yaoctvw9
Puetzer JL, Petitte JN, Loboa EG. Comparative review of growth factors for induction of three-dimensional in vitro chondrogenesis in human mesenchymal stem cells isolated from bone marrow and adipose tissue. Tissue Eng Part B Rev. 2010; 16: 435-444. Ref.: https://tinyurl.com/y8drpuln
Zhang L, Su P, Xu C, Yang J, Yu W, et al. Chondrogenic differentiation of human mesenchymal stem cells: a comparison between micromass and pellet culture systems. Biotechnology Lett. 2010; 32: 1339-1346. Ref.: https://tinyurl.com/yaoctvw9
Godara P, McFarland CD, Nordon RE. Design of bioreactors for mesenchymal stem cell tissue engineering. J Chem Technol Biotechnol. 2008; 83: 408-420. Ref.: https://tinyurl.com/y7ungm2f
Bancroft GN, Sikavitsas VI, Mikos AG. Design of a flow perfusion bioreactor system for bone tissue-engineering applications. Tissue Eng. 2003; 9: 549-554. Ref.: https://tinyurl.com/y6uqnsq8
Xu F, Xu L, Wang Q, Zhou Y, Ye Z, et al. A three-dimensional dynamic coculture system enabling facile cell separation for chondrogenesis of mesenchymal stem cells. Biochemical Engineering Journal. 2015; 103: 68-76. Ref.: https://tinyurl.com/y6uqnsq8
Vunjak-Novakovic G, Freed LE, Biron RJ, Langer R. Effects of mixing on the composition and morphology of tissue-engineered cartilage. AIChE Journal. 1996; 42: 850-860. Ref.: https://tinyurl.com/y6vwvlj7
Song K, Li L, Li W, Zhu Y, Jiao Z, et al. Three-dimensional dynamic fabrication of engineered cartilage based on chitosan/gelatin hybrid hydrogel scaffold in a spinner flask with a special designed steel frame. Mater Sci Eng C Mater Biol Appl. 2015; 55: 384-392. Ref.: https://tinyurl.com/ycne5b3f
Janjanin S, Li WJ, Morgan MT, Shanti RM, Tuan RS. Mold-Shaped, Nanofiber Scaffold-Based Cartilage Engineering Using Human Mesenchymal Stem Cells and Bioreactor. J Surg Res. 2008; 149: 47-56. Ref.: https://tinyurl.com/yd3d3zt4
Mygind T, Stiehler M, Baatrup A, Li H, Zou X, Flyvbjerg A. Mesenchymal stem cell ingrowth and differentiation on coralline hydroxyapatite scaffolds. Biomaterials. 2007; 28: 1036-1047. Ref.: https://tinyurl.com/yaclvsol
Stiehler M, Bünger C, Baatrup A, Lind M, Kassem M, et al. Effect of dynamic 3-D culture on proliferation, distribution, and osteogenic differentiation of human mesenchymal stem cells. J Biomed Mater Res A. 2009; 89: 96-107. Ref.: https://tinyurl.com/ya46zzp2
Chen HC, Hu YC. Bioreactors for tissue engineering. Biotechnol Lett. 2006; 28: 1415-1423. Ref.: https://tinyurl.com/y8v4dq4t
Freed LE, Vunjak-Novakovic G. Tissue Enginnering Bioreactors, In: Principles of Tissue Engineering, Lanza R, Langer R, and Vacanti J, Editors. Academic Press: San Diego. 2000; 143-156.
Meinel L, Karageorgiou V, Fajardo R, Snyder B, Shinde-Patil V, et al.Bone tissue engineering using human mesenchymal stem cells: effects of scaffold material and medium flow. Ann Biomed Eng. 2004; 32: 112-122. Ref.: https://tinyurl.com/y8yeocea
Vunjak-Novakovic G, Obradovic B, Martin I, Bursac PM, Langer R, et al. Dynamic cell seeding of polymer scaffolds for cartilage tissue engineering. Biotechnol Prog. 1998; 14: 193-202. Ref.: https://tinyurl.com/y95zpo8q
Schwarz RP, Goodwin TJ, Wolf DA. Cell culture for three-dimensional modeling in rotating-wall vessels: an application of simulated microgravity. J Tissue Cult Methods. 1992; 14: 51-57. Ref.: https://tinyurl.com/ycjs4ylu
Schwarz R, Wolf D, Trinh T. Rotating cell culture vessel. 1991: US.
Schwarz R, Wolf D. High-aspect rotating cell culture vessel. 1991: US.
Granet C, Laroche N, Vico L, Alexandre C, Lafage-Proust MH. Rotating-wall vessels, promising bioreactors for osteoblastic cell culture: comparison with other 3D conditions. Med Biol Eng Comput. 1998; 36: 513-519. Ref.: https://tinyurl.com/yd2lq5mq
Song K, Yang Z, Liu T, Zhi W, Li X, et al. Fabrication and detection of tissue-engineered bones with bio-derived scaffolds in a rotating bioreactor. Biotechnol Appl Biochem. 2006; 45: 65-74. Ref.: https://tinyurl.com/yd3kkjbt
Langer R, Martin I, Pellis NR, Vunjak-Novakovic G. Tissue engineering of cartilage in space. Proc Natl Acad Sci USA. 1997; 94: 13885-13890. Ref.: https://tinyurl.com/ybxycsp6
Ohyabu Y, Kida N, Kojima H, Taguchi T, Tanaka J, et al. Cartilaginous tissue formation from bone marrow cells using rotating wall vessel (RWV) bioreactor. Biotechnol Bioeng. 2006; 95: 1003-1008. Ref.: https://tinyurl.com/ybvxgrn7
Sakai S, Mishima H, Ishii T, Akaogi H, Yoshioka T, et al. Rotating three-dimensional dynamic culture of adult human bone marrow-derived cells for tissue engineering of hyaline cartilage. J Orthop Res. 2009; 27: 517-521. Ref.: https://tinyurl.com/y7ekt3td
Yoshioka T, Mishima H, Ohyabu Y, Sakai S, Akaogi H, et al. Repair of large osteochondral defects with allogeneic cartilaginous aggregates formed from bone marrow-derived cells using RWV bioreactor. J Orthop Res. 2007; 25: 1291-1298. Ref.: https://tinyurl.com/y99nrbkg
Marolt D, Augst A, Freeda LE, Veparic C, Fajardo R, et al. Bone and cartilage tissue constructs grown using human bone marrow stromal cells, silk scaffolds and rotating bioreactors. Biomaterials. 2006; 27: 6138-6149. Ref.: https://tinyurl.com/ybpugwzf
Chen HC, Sung LY, Lo WH, Chuang CK, Wang YH, et al. Combination of baculovirus-expressed BMP-2 and rotating-shaft bioreactor culture synergistically enhances cartilage formation. Gene Ther, 2008. 15: 309-317. Ref.: https://tinyurl.com/y7p8mzdm
Lu CH, Lin KJ, Chiu HY, Chen CY, Yen TC, et al. Improved chondrogenesis and engineered cartilage formation from TGF-beta3-expressing adipose-derived stem cells cultured in the rotating-shaft bioreactor. Tissue Eng Part A. 2012; 18: 2114-2124. Ref.: https://tinyurl.com/y9b8x7yf
Chen HC, Lee HP, Sung ML, Liao CJ, Hu YC. A novel rotating-shaft bioreactor for two-phase cultivation of tissue-engineered cartilage. Biotechnol Prog. 2004; 20: 1802-1809. Ref.: https://tinyurl.com/ybouj39j
Singh V. Disposable bioreactor for cell culture using wave-induced agitation. Cytotechnology. 1999; 30: 149-158. Ref.: https://tinyurl.com/ydfkh3on
Kadarusman J, Bhatia R, McLaughlin J, Lin WR. Growing cholesterol-dependent NS0 myeloma cell line in the wave bioreactor system: overcoming cholesterol-polymer interaction by using pretreated polymer or inert fluorinated ethylene propylene. Biotechnol Prog. 2005; 21: 1341-1346. Ref.: https://tinyurl.com/y86x8vn7
Zhang Y, Meng H, Hou S. Method for preparing mesenchymal stem cells in scale by use of bioreactor. Union Stem Cell & Gene Engineering Co., Ltd., Peop Rep China. 2011; 6.
Mizuno S, Allemann F, Glowacki J. Effects of medium perfusion on matrix production by bovine chondrocytes in three-dimensional collagen sponges. J Biomed Mater Res. 2001; 56: 368-375. Ref.: https://tinyurl.com/y988sed3
Alves da Silva ML, Martins A, Costa-Pinto AR, Correlo VM, Sol P. Chondrogenic differentiation of human bone marrow mesenchymal stem cells in chitosan-based scaffolds using a flow-perfusion bioreactor. J Tissue Eng Regen Med. 2011; 5: 722-732. Ref.: https://tinyurl.com/y9qg3jjn
Davisson T, Sah RL, Ratcliffe A. Perfusion increases cell content and matrix synthesis in chondrocyte three-dimensional cultures. Tissue Eng. 2002; 8: 807-816. Ref.: https://tinyurl.com/yczhjxrm
Pazzano D, Mercier KA, Moran JM, Fong SS, DiBiasio DD. Comparison of chondrogensis in static and perfused bioreactor culture. Biotechnol Prog. 2000; 16: 893-896. Ref.: https://tinyurl.com/ydbq2kvcb
Santoro R, Olivares AL, Brans G, Wirz D, Longinotti C, et al. Bioreactor based engineering of large-scale human cartilage grafts for joint resurfacing. Biomaterials. 2010; 31: 8946-8952. Ref.: https://tinyurl.com/yc8jwgtv
Gomes ME, Sikavitsas VI, Behravesh E, Reis RL, Mikos AG. Effect of flow perfusion on the osteogenic differentiation of bone marrow stromal cells cultured on starch-based three-dimensional scaffolds. J Biomed Mater Res A. 2003; 67: 87-95. Ref.: https://tinyurl.com/ycl8ak48
Yeatts AB, Fisher JP. Bone tissue engineering bioreactors: dynamic culture and the influence of shear stress. Bone. 2011; 48: 171-181. Ref.: https://tinyurl.com/ybrgtq6x
Bancroft GN, Sikavitsas VI, van den Dolder J, Sheffield TL, Ambrose CG, et al. Fluid flow increases mineralized matrix deposition in 3D perfusion culture of marrow stromal osteoblasts in a dose-dependent manner. Proc Natl Acad Sci USA. 2002; 99: 12600-12605. Ref.: https://tinyurl.com/yc6dftpf
Shahin K, Doran PM. Strategies for enhancing the accumulation and retention of extracellular matrix in tissue-engineered cartilage cultured in bioreactors. Plos One. 2011; 6: 15. Ref.: https://tinyurl.com/ydz2du7w
Yeatts AB, Fisher JP. Tubular Perfusion System for the Long-Term Dynamic Culture of Human Mesenchymal Stem Cells. Tissue Eng Part C. 2011; 17: 337-348. Ref.: https://tinyurl.com/y8arskg6
Coates EE, Riggin CN, Fisher JP. Photocrosslinked alginate with hyaluronic acid hydrogels as vehicles for mesenchymal stem cell encapsulation and chondrogenesis. J Biomed Mater Res A. 2013; 101: 1962-1970. Ref.: https://tinyurl.com/ycv6bngg
Guo T, Yu L, Lim CG, Goodley AS, Xiao X, et al. Effect of Dynamic Culture and Periodic Compression on Human Mesenchymal Stem Cell Proliferation and Chondrogenesis. Ann Biomed Eng. 2016; 44: 2103-2113. Ref.: https://tinyurl.com/y7dyynrb
Knazek RA, Wu YW, Aebersold PM, Rosenberg SA. Culture of human tumor infiltrating lymphocytes in hollow fiber bioreactors. J Immunol Methods. 1990; 127: 29-37. Ref.: https://tinyurl.com/y96ddz8g
Nordon RE, Schindhelm K. Design of hollow fiber modules for uniform shear elution affinity cell separation. Artif Organs. 1997; 21: 107-115. Ref.: https://tinyurl.com/yam24fuw
Abu-Absi SF, Seth G, Narayanan RA, Groehler K, Lai P, et al. Characterization of a hollow fiber bioartificial liver device. Artif Organs. 2005; 29: 419-422. Ref.: https://tinyurl.com/yd76fv74
Meng Q, Zhang G, Wu D. Hepatocyte culture in bioartificial livers with different membrane characteristics. Biotechnology Lett. 2004; 26: 1407-1412. Ref.: https://tinyurl.com/yafmn2zp
Malone CC, Schiltz PM, Mackintosh AD, Beutel LD, Heinemann FS, et al. Characterization of human tumor-infiltrating lymphocytes expanded in hollow-fiber bioreactors for immunotherapy of cancer. Cancer Biother Radiopharm. 2001; 16: 381-390. Ref.: https://tinyurl.com/ya29jwnk
Potter K, Butler JJ, Adams C, Fishbein KW, McFarland EW, et al. Cartilage formation in a hollow fiber bioreactor studied by proton magnetic resonance microscopy. Matrix Biol. 1998; 17: 513-523. Ref.: https://tinyurl.com/ycbkyrzq
Potter K, Butler JJ, Horton WE, Spencer RG. Response of engineered cartilage tissue to biochemical agents as studied by proton magnetic resonance microscopy. Arthritis Rheum. 2000; 43: 1580-1590. Ref.: https://tinyurl.com/y757q7vw
Ellis SJ, Velayutham M, Velan SS, Petersen EF, Zweier JL, et al. EPR oxygen mapping (EPSOM) of engineered cartilage grown in a hollow-fiber bioreactor. Magn Reson Med. 2001; 46: 819-826. Ref.: https://tinyurl.com/y7oab3az
Potter K, Kidder LH, Levin IW, Lewis EN, Spencer RG. Imaging of collagen and proteoglycan in cartilage sections using Fourier transform infrared spectral imaging. Arthritis Rheum. 2001; 44: 846-855. Ref.: https://tinyurl.com/y8krneov
Kim M, Bi X, Horton WE, Spencer RG, Camacho NP, et al. Fourier transform infrared imaging spectroscopic analysis of tissue engineered cartilage: histologic and biochemical correlations. J Biomed Opt. 2005; 10: 031105. Ref.: https://tinyurl.com/yaqanqqq
Liu T, et al. Method for amplification of bone marrow-derived mesenchymal stem cells under dynamic three-dimensional conditions. Dalian University of Technology, Peop Rep China. 2007; 13.
Antwiler GD, Peters RL, Windmiller DA. Method of reseeding adherent cells grown in a hollow fiber bioreactor system. CaridianBCT, Inc., USA. Cont.-in-part of U.S. Ser. No. 42,763. 2011; 9.
Antwiler GD. Culture of mesenchymal stem cells including seeding on a hollow-fiber membrane. Gambro BCT, Inc., USA. 2007; 8.
De Napoli IE, Scaglione S, Giannoni P, Quarto R, Catapano G. Mesenchymal stem cell culture in convection-enhanced hollow fibre membrane bioreactors for bone tissue engineering. J Membr Sci. 2011; 379: 341-352. Ref.: https://tinyurl.com/yarx8s82
Li X, Liu T, Song K, Ma X, Cui Z. Culture and expansion of mesenchymal stem cells in air-lift loop hollow fiber membrane bioreactor. Gaoxiao Huaxue Gongcheng Xuebao. 2008; 22: 985-991. Ref.: https://tinyurl.com/y7z2p5qx
Li X, Liu T, Song K, Ma X, Cui Z. Hypoxic culture and expansion of mesenchymal stem cells in airlift loop hollow fiber membrane bioreactor. Cell Res. 2008; 18: S169. Ref.: https://tinyurl.com/ycyqxy56
Nold P, Brendel C, Neubauer A, Bein G, Hackstein H. Good manufacturing practice-compliant animal-free expansion of human bone marrow derived mesenchymal stroma cells in a closed hollow-fiber-based bioreactor. Biochem Biophys Res Commun. 2013; 430: 325-330. Ref.: https://tinyurl.com/yb2sylz2
Chresand TJ, Gillies RJ, Dale BE. Optimum fiber spacing in a hollow fiber bioreactor. Biotechnol Bioeng. 1988; 32: 983-992. Ref.: https://tinyurl.com/y7yrv6ml
Wang TY, Wu JH. A continuous perfusion bioreactor for long-term bone marrow culture. Ann N Y Acad Sci. 1992; 665: 274-284. Ref.: https://tinyurl.com/ycouyqbb
Koller MR, Bender JG, Miller WM, Papoutsakis ET. Expansion of primitive human hematopoietic progenitors in a perfusion bioreactor system with IL-3, IL-6, and stem cell factor. Biotechnology. 1993; 11: 358-363. Ref.: https://tinyurl.com/y8u42mzv
Peng CA, Palsson BO. Cell growth and differentiation on feeder layers is predicted to be influenced by bioreactor geometry. Biotechnol Bioeng. 1996; 50: 479-492. Ref.: https://tinyurl.com/y8u42mzv
Palsson BO, Paek SH, Schwartz RM, Palsson M, Lee GM, et al. Expansion of human bone marrow progenitor cells in a high cell density continuous perfusion system. Biotechnology. 1993; 11: 368-372. Ref.: https://tinyurl.com/y8oy8h9g
Koller MR, Emerson SG, Palsson BO. Large-scale expansion of human stem and progenitor cells from bone marrow mononuclear cells in continuous perfusion cultures. Blood. 1993; 82: 378-384. Ref.: https://tinyurl.com/y8kakstw
Roy P, Harihara B, Arno Tilles W, Martin Yarmush L, Mehmet Toner. Analysis of oxygen transport to hepatocytes in a flat-plate microchannel bioreactor. Ann Biomed Eng, 2001. 29: 947-955. Ref.: https://tinyurl.com/y79xs2y4
Gemmiti CV, Guldberg RE. Fluid flow increases type II collagen deposition and tensile mechanical properties in bioreactor-grown tissue-engineered cartilage. Tissue Eng. 2006; 12: 469-479. Ref.: https://tinyurl.com/ycumwcv8
Chen S, Wang S, Xie T. Restricting self-renewal signals within the stem cell niche: multiple levels of control. Curr Opin Genet Dev. 2011; 21: 684-689. Ref.: https://tinyurl.com/y6uzyvbz
Brizzi MF, Tarone G, Defilippi P. Extracellular matrix, integrins, and growth factors as tailors of the stem cell niche. Curr Opin Cell Biol. 2012; 24: 645-651. Ref.: https://tinyurl.com/yaa6fd2r
Kuster MS, Wood GA, Stachowiak GW, Gächter A. Joint load considerations in total knee replacement. Journal of Bone and Joint Surgery-British Volume. 1997; 79B: 109-113. Ref.: https://tinyurl.com/y8cy98kp
Marlovits S, Tichy B, Truppe M, Gruber D, Vécsei V. Chondrogenesis of aged human articular cartilage in a scaffold-free bioreactor. Tissue Eng. 2003; 9: 1215-1226. Ref.: https://tinyurl.com/y8g6aswf
Concaro S, Gustavson F, Gatenholm P. Bioreactors for tissue engineering of cartilage. Adv Biochem Eng Biotechnol. 2009; 112: 125-143. Ref.: https://tinyurl.com/y8ehgrej
Korhonen RK, Laasanen MS, Töyräs J, Rieppo J, Hirvonen J. Comparison of the equilibrium response of articular cartilage in unconfined compression, confined compression and indentation. J Biomech. 2002; 35: 903-909. Ref.: https://tinyurl.com/yb77sdvz
Buschmann MD, Gluzband YA, Grodzinsky AJ, Hunziker EB. Mechanical compression modulates matrix biosynthesis in chondrocyte agarose culture. J Cell Science. 1995; 108: 1497-1508. Ref.: https://tinyurl.com/ybwlvgqa
Sah RL, Doong JY, Grodzinsky AJ, Plaas AH, Sandy JD. Effects of compression on the loss of newly synthesized proteoglycans and proteins from cartilage explants. Arch Biochem Biophys. 1991; 286: 20-29. Ref.: https://tinyurl.com/y7br3kgv
Mow VC, Wang CC. Some bioengineering considerations for tissue engineering of articular cartilage. Clin Orthop Relat Res. 1999; 204-223. Ref.: https://tinyurl.com/yatwlpff
von Eisenhart R, Adam C, Steinlechner M, Müller-Gerbl M, Eckstein F. Quantitative determination of joint incongruity and pressure distribution during simulated gait and cartilage thickness in the human hip joint. J Orthop Res. 1999; 17: 532-539. Ref.: https://tinyurl.com/ycxqsh8o
Davisson T, Kunig S, Chen A, Sah R, Ratcliffe A. Static and dynamic compression modulate matrix metabolism in tissue engineered cartilage. J Orthop Res. 2002; 20: 842-848. Ref.: https://tinyurl.com/y8yxz2wm
Huang CY, Hagar KL, Frost LE, Sun Y, Cheung HS. Effects of cyclic compressive loading on chondrogenesis of rabbit bone-marrow derived mesenchymal stem cells. Stem Cells. 2004; 22: 313-323. Ref.: https://tinyurl.com/y9z5aybt
Terraciano V, Hwang N, Moroni L, Park HB, Zhang Z. Differential response of adult and embryonic mesenchymal progenitor cells to mechanical compression in hydrogels. Stem Cells. 2007; 25: 2730-2738. Ref.: https://tinyurl.com/ycebr2vz
Huang CY, Reuben PM, Cheung HS. Temporal expression patterns and corresponding protein inductions of early responsive genes in rabbit bone marrow-derived mesenchymal stem cells under cyclic compressive loading. Stem Cells. 2005; 23: 1113-1121. Ref.: https://tinyurl.com/ybvhum6u
Campbell JJ, Lee DA, Bader DL. Dynamic compressive strain influences chondrogenic gene expression in human mesenchymal stem cells. Biorheology. 2006; 43: 455-470. Ref.: https://tinyurl.com/ybzfx4fk
Bian L, Fong JV, Lima EG, Stoker AM, Ateshian GA. Dynamic mechanical loading enhances functional properties of tissue-engineered cartilage using mature canine chondrocytes. Tissue Eng Part A. 2010; 16: 1781-1790. Ref.: https://tinyurl.com/yd2zeah9
Poole AR, Kojima T, Yasuda T, Mwale F, Kobayashi M. Composition and structure of articular cartilage: a template for tissue repair. Clin Orthop Relat Res. 2001; 391: S26-33. Ref.: https://tinyurl.com/ycz7hgtg
Mizuno S, Tateishi T, Ushida T, Glowacki J. Hydrostatic fluid pressure enhances matrix synthesis and accumulation by bovine chondrocytes in three-dimensional culture. J Cell Physiol. 2002. 193: 319-327. Ref.: https://tinyurl.com/yaglk592
Meyer EG, Buckley CT, Steward AJ, Kelly DJ. The effect of cyclic hydrostatic pressure on the functional development of cartilaginous tissues engineered using bone marrow derived mesenchymal stem cells. Journal of the Mechanical Behavior of Biomedical Materials. 2011; 4: 1257-1265. Ref.: https://tinyurl.com/y9mnzgo3
Hansen U, Schünke M, Domm C, Ioannidis N, Hassenpflug J, et al. Combination of reduced oxygen tension and intermittent hydrostatic pressure: a useful tool in articular cartilage tissue engineering. Journal of Biomechanics. 2001; 34: 941-949. Ref.: https://tinyurl.com/ydxomvvq
Hu JC, Athanasiou KA. The effects of intermittent hydrostatic pressure on self-assembled articular cartilage constructs. Tissue Engineering. 2006; 12: 1337-1344. Ref.: https://tinyurl.com/ya4zkgql
Ogawa R, Mizuno S, Murphy GF, Orgill DP. The effect of hydrostatic pressure on three-dimensional chondroinduction of human adipose-derived stem cells. Tissue Engineering Part A. 2009; 15: 2937-2945. Ref.: https://tinyurl.com/y992o3me
Luo ZJ, Seedhom BB. Light and low-frequency pulsatile hydrostatic pressure enhances extracellular matrix formation by bone marrow mesenchymal cells: an in-vitro study with special reference to cartilage repair. Proc Inst Mech Eng H. 2007; 221: 499-507. Ref.: https://tinyurl.com/y8czmnam
Miyanishi K, Trindade MC, Lindsey DP, Beaupré GS, Carter DR. Effects of hydrostatic pressure and transforming growth factor-beta 3 on adult human mesenchymal stem cell chondrogenesis in vitro. Tissue Engineering. 2006. 12: 1419-1428. Ref.: https://tinyurl.com/y8pgwyv2
Seidel JO, Pei M, Gray ML, Langer R, Freed LE. Long-term culture of tissue engineered cartilage in a perfused chamber with mechanical stimulation. Biorheology. 2004; 41: 445-458. Ref.: https://tinyurl.com/y88wsnjt
Wimmer MA1, Grad S, Kaup T, Hänni M, Schneider E. Tribology approach to the engineering and study of articular cartilage. Tissue Eng. 2004. 10: 1436-1445. Ref.: https://tinyurl.com/ydcvz9xw
Wimmer MA, Alini M, Grad S. The effect of sliding velocity on chondrocytes activity in 3D scaffolds. J Biomech. 2009; 42: 424-429. Ref.: https://tinyurl.com/y8r68cg6
van Donkelaar CC, Schulz RM. Review on patents for mechanical stimulation of articular cartilage tissue engineering. Recent Patents on Biomedical Engineering. 2008; 1: 1-12. Ref.: https://tinyurl.com/ycm36q77
Nazempour A, Quisenberry CR, Van Wie BJ, Abu-Lail NI. Nanomechanics of engineered articular cartilage: synergistic influences of transforming growth factor-β3 and oscillating pressure. J Nanoscience Nanotechnology. 2016; 16: 3136-3145. Ref.: https://tinyurl.com/ybx4obv2
Quisenberry CR, Nazempour A, Van Wie BJ, Abu-Lail NI. Expression of N-Cadherins on Chondrogenically Differentiating Human Adipose Derived Stem Cells Using Single-Molecule Force Spectroscopy. J Nanomedicine Res. 2016; 3: 1-13. Ref.: https://tinyurl.com/y8k9q9ml
Quisenberry CR, Nazempour A, Van Wie BJ, Abu-Lail NI. Evaluation of β1-integrin expression on chondrogenically differentiating human adipose-derived stem cells using atomic force microscopy. Biointerphases. 2016; 11: 021005. https://tinyurl.com/y8b3h5v8
Hao H, Chen G, Liu J, Ti D, Zhao Y, et al. Culturing on Wharton's jelly extract delays mesenchymal stem cell senescence through p53 and p16INK4a/pRb pathways. Plos One. 2013; 8: 13. Ref.: https://tinyurl.com/y8gunpuf
Nazempour A, et al. Combined effects of oscillating hydrostatic pressure, perfusion and encapsulation in a novel bioreactor for enhancing extracellular matrix synthesis by bovine chondrocytes. Cell Tissue Res. 2017; 7: 017-2651.
Kawanishi M, Oura A, Furukawa K, Fukubayashi T, Nakamura K, et al. Redifferentiation of dedifferentiated bovine articular chondrocytes enhanced by cyclic hydrostatic pressure under a gas-controlled system. Tissue Eng. 2007; 13: 957-964. Ref.: https://tinyurl.com/y8t9z766
Gharravi AM, Orazizadeh M, Hashemitabar M. Fluid-induced low shear stress improves cartilage like tissue fabrication by encapsulating chondrocytes. Cell Tissue Bank. 2015; 17: 117-122. Ref.: https://tinyurl.com/y6uo3dhm
Benya PD, Shaffer JD. Dedifferentiated chondrocytes reexpress the differentiated collagen phenotype when cultured in agarose gels. Cell. 1982; 30: 215-224. Ref.: https://tinyurl.com/y98nldre
Kessler MW, Grande DA. Tissue engineering and cartilage. Organogenesis. 2008; 4: 28-32. Ref.: https://tinyurl.com/y9gf5u26
Buschmann MD, Gluzband YA, Grodzinsky AJ, Kimura JH, Hunziker EB. Chondrocytes in agarose culture synthesize a mechanically functional extracellular matrix. J Orthop Res. 1992; 10: 745-758. Ref.: https://tinyurl.com/ybnosqgj
Van Wie BJ, Brouns TM, Elliot ML, Davis WC. A novel continuos centrifugal bioreactor for high-density cultivation of mammalian and microbial-cells. Biotechnol Bioeng. 1991; 38: 1190-1202. Ref.: https://tinyurl.com/y8lghg32
Detzel CJ, Van Wie BJ. Use of a centrifugal bioreactor for cartilaginous tissue formation from isolated chondrocytes. Biotechnology Progress. 2011; 27: 451-459. Ref.: https://tinyurl.com/y873ggwy
Van Wie BJ, Elliott ML, Lee JM, Scott CD. Development and characterization of a continuous centrifugal bioreactor. 1986. Ref.: https://tinyurl.com/y7yal3jm
Mauck RL, Nicoll SB, Seyhan SL, Ateshian GA, Hung CT. Synergistic action of growth factors and dynamic loading for articular cartilage tissue engineering. Tissue Engineering. 2003; 9: 597-611. Ref.: https://tinyurl.com/y9jonhz5
Sophia Fox AJ, Bedi A, Rodeo SA. The basic science of articular cartilage: structure, composition, and function. Sports Health. 2009; 1: 461-468. Ref.: https://tinyurl.com/ybj2bu9y
Kesti M, Müller M, Becher J, Schnabelrauch M, D'Este M. A versatile bioink for three-dimensional printing of cellular scaffolds based on thermally and photo-triggered tandem gelation. Acta Biomater. 2015; 11: 162-172. Ref.: https://tinyurl.com/y7zlq4y6
Das S, Pati F, Choi YJ, Rijal G, Shim JH, et al. Bioprintable, cell-laden silk fibroin-gelatin hydrogel supporting multilineage differentiation of stem cells for fabrication of three-dimensional tissue constructs. Acta Biomater. 2015; 11: 233-246. Ref.: https://tinyurl.com/y95kcppj
Shoichet MS, Li RH, White ML, Winn SR. Stability of hydrogels used in cell encapsulation: An in vitro comparison of alginate and agarose. Biotechnol Bioeng. 1996; 50: 374-381. Ref.: https://tinyurl.com/yd8q3ltf
Smith CM, Stone AL, Parkhill RL, Stewart RL, Simpkins MW, et al. Three-dimensional bioassembly tool for generating viable tissue-engineered constructs. Tissue Eng. 2004; 10: 1566-76. Ref.: https://tinyurl.com/y9dlduvu
Nazempour A, Van Wie BJ. Chondrocytes, mesenchymal stem sells, and their combination in articular cartilage regenerative medicine. Annals of Biomedical Engineering. 2016; 44: 1325-1354. Ref.: https://tinyurl.com/ydyjukdj
Scaglione S, Wendt D, Miggino S, Papadimitropoulos A, Fato M, et al. Effects of fluid flow and calcium phosphate coating on human bone marrow stromal cells cultured in a defined 2D model system. J Biomed Mater Res A. 2008; 86: 411-419. Ref.: https://tinyurl.com/ybdqy8h7
Kreke MR, Huckle WR, Goldstein AS. Goldstein. Fluid flow stimulates expression of osteopontin and bone sialoprotein by bone marrow stromal cells in a temporally dependent manner. Bone, 2005; 36: 1047-1055. Ref.: https://tinyurl.com/ybe9rl7q
Kapur S, Baylink DJ, Lau KH. Fluid flow shear stress stimulates human osteoblast proliferation and differentiation through multiple interacting and competing signal transduction pathways. Bone. 2003; 32: 241-251. Ref.: https://tinyurl.com/ydyo7ses
Lee SH, Shin H. Matrices and scaffolds for delivery of bioactive molecules in bone and cartilage tissue engineering. Advanced Drug Delivery Reviews. 2007; 59: 339-359. Ref.: https://tinyurl.com/ycc5orob
Ecker DM, Jones SD, Levine HL. The therapeutic monoclonal antibody market. MAbs. 2015; 7: 9-14. Ref.: https://tinyurl.com/ycdchsan
Detzel CJ, Mason DJ, Davis WC, van Wie BJ. Kinetic simulation of a centrifugal bioreactor for high population density hybridoma culture. Biotechnol Prog. 2009; 25: 1650-1659.