Biomedical Engineering Reference
In-Depth Information
[7] Huang CP, J Lu, H Seon, AP Lee, LA Flanagan, HY Kim, AJ Putnam and NL Jeon (2009).
Engineering microscale cellular niches for three-dimensional multicellular co-cultures. Lab on a
Chip 9: 1740-1748.
[8] Wright D, B Rajalingam, S Selvarasah, MR Dokmeci and A Khademhosseini (2007). Generation
of static and dynamic patterned co-cultures using microfabricated parylene-C stencils. Lab on a
Chip 7: 1272-1279.
[9] Skelley AM, O Kirak, H Suh, R Jaenisch and J Voldman (2009). Microfluidic control of cell
pairing and fusion. Nature Methods 6: 147-152.
[10]
Fukuda J, A Khademhosseini, J Yeh, G Eng, J Cheng, OC Farokhzad and R Langer (2006).
Micropatterned cell co-cultures using layer-by-layer deposition of extracellular matrix compo-
nents. Biomaterials 27: 1479-1486.
[11]
Hui EEa and SN Bhatia (2007). Micromechanical control of cell-cell interactions. Proceedings
of the National Academy of Sciences of the USA 104: 5722-5726.
[12]
Dertinger SKW, DT Chiu, NL Jeon and GM Whitesides (2001). Generation of gradients having
complex shapes using microfluidic networks. Analytical Chemistry 73: 1240-1246.
[13]
Zheng W, Z Wang, W Zhang and X Jiang (2010). A simple PDMS-based microfluidic channel
design that removes bubbles for long-term on-chip culture of mammalian cells. Lab on a Chip
10: 2906-2910.
[14]
Korin N, A Bransky, U Dinnar and S Levenberg (2009). Periodic “flow-stop” perfusion micro-
channel bioreactors for mammalian and human embryonic stem cell long-term culture.
Biomedical Microdevices 11: 87-94.
[15]
Throm Quinlan AM, LN Sierad, AK Capulli, LE Firstenberg and KL Billiar (2011). Combining
dynamic stretch and tunable stiffness to probe cell mechanobiology
in vitro
. PLoS One 6:
e23272.
[16]
Rowlands AS, PA George and JJ Cooper-White (2008). Directing osteogenic and myogenic
differentiation of MSCs: interplay of stiffness and adhesive ligand presentation. American
Journal of Physiology - Cell Physiology 295: C1037-C1044.
[17]
Stevens MM and JH George (2005). Exploring and engineering the cell surface interface. Science
310: 1135-1138.
[18]
Sniadecki NJ, A Anguelouch, MT Yang, CM Lamb, Z Liu, SB Kirschner, Y Liu, DH Reich and
CS Chen (2007). Magnetic microposts as an approach to apply forces to living cells. Proceedings
of the National Academy of Sciences of the USA 104: 14553-14558.
[19]
Flaim CJ, S Chien and SN Bhatia (2005). An extracellular matrix microarray for probing cellular
differentiation. Nature Methods 2: 119-125.
[20]
Chen CS, E Ostuni, GM Whitesides and DE Ingber (2000). Using self-assembled monolayers to
pattern ECM proteins and cells on substrates. Methods in Molecular Biology 139: 209-219.
[21]
Koepsel JT and WL Murphy (2009). Patterning discrete stem cell culture environments via
localized self-assembled monolayer replacement. Langmuir 25: 12825-12834.
[22]
Ruiz SA and CS Chen (2008). Emergence of patterned stem cell differentiation within multicellular
structures. Stem Cells 26: 2921-2927.
[23]
Hosseinkhani H, M Hosseinkhani, F Tian, H Kobayashi and Y Tabata. (2006). Osteogenic
differentiation of mesenchymal stem cells in self-assembled peptide-amphiphile nanofibers.
Biomaterials 27: 4079-4086.
[24]
Re'em T, O Tsur-Gang and S Cohen. (2010). The effect of immobilized RGD peptide in macro-
porous alginate scaffolds on TGFbeta1-induced chondrogenesis of human mesenchymal stem
cells. Biomaterials 31: 6746-6755.
[25]
Joy A, DM Cohen, A Luk, E Anim-Danso, C Chen and J Kohn. (2011). Control of surface
chemistry, substrate stiffness, and cell function in a novel terpolymer methacrylate library.
Langmuir 27: 1891-1899.
[26]
Derda R, L Li, BP Orner, RL Lewis, JA Thomson and LL Kiessling. (2007). Defined substrates
for human embryonic stem cell growth identified from surface arrays. ACS Chemical Biology 2:
347-355.
[27]
Anderson DG, S Levenberg and R Langer. (2004). Nanoliter-scale synthesis of arrayed bioma-
terials and application to human embryonic stem cells. Nature Biotechnology 22: 863-866.
